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SolutionsManual
1AGlencoeProgramStudentEditionForensicsLaboratoryManual,TeacherTeacherWraparoundEditionEditionSupplementalProblemsTeacherChapterResourcesAdditionalChallengeProblemsMiniLabWorksheetsPre-AP/CriticalThinkingProblemsPhysicsLabWorksheetsPhysicsTestPrep:StudyingfortheStudyGuideEnd-of-CourseExam,StudentEditionSectionQuizzesPhysicsTestPrep:StudyingfortheReinforcementEnd-of-CourseExam,TeacherEditionEnrichmentConnectingMathtoPhysicsTransparencyMastersSolutionsManualTransparencyWorksheetsChapterAssessmentTechnologyAnswerKeyMakerTeacherClassroomResourcesExamView®ProTeachingTransparenciesInteractiveChalkboardLaboratoryManual,StudentEditionMcGraw-HillLearningNetworkLaboratoryManual,TeacherEditionStudentWorks™CD-ROMProbewareLaboratoryManual,StudentTeacherWorks™CD-ROMEditionphysicspp.comWebsiteProbewareLaboratoryManual,TeacherEditionForensicsLaboratoryManual,StudentEditionCopyright©byTheMcGraw-HillCompanies,Inc.Allrightsreserved.Permissionisgrantedtoreproducethematerialcontainedhereinontheconditionthatsuchmaterialberepro-ducedonlyforclassroomuse;beprovidedtostudents,teachers,andfamilieswithoutcharge;andbeusedsolelyinconjunctionwiththePhysics:PrinciplesandProblemsprogram.Anyotherreproduction,foruseorsale,isprohibitedwithoutpriorwrittenpermissionofthepublisher.Sendallinquiriesto:Glencoe/McGraw-Hill8787OrionPlaceColumbus,Ohio43240ISBN0-07-865893-4PrintedintheUnitedStatesofAmerica123456789045090807060504
2ContentsTotheTeacher......................ivChapter1Chapter17APhysicsToolkit....................1ReflectionandMirrors..............357Chapter2Chapter18RepresentingMotion................15RefractionandLenses..............377Chapter3Chapter19AcceleratedMotion.................29InterferenceandDiffraction.........399Chapter4Chapter20ForcesinOneDimension............61StaticElectricity...................413Chapter5Chapter21ForcesinTwoDimensions...........87ElectricFields.....................427Chapter6Chapter22MotioninTwoDimensions.........115CurrentElectricity.................445Chapter7Chapter23Gravitation.......................141SeriesandParallelCircuits..........463Chapter8Chapter24RotationalMotion.................169MagneticFields...................485Chapter9Chapter25MomentumandItsConservation....193ElectromagneticInduction..........501Chapter10Chapter26Energy,Work,andSimpleMachines..225Electromagnetism..................517Chapter11Chapter27EnergyandItsConservation.........247QuantumTheory..................531Chapter12Chapter28ThermalEnergy...................271TheAtom........................545Chapter13Chapter29StatesofMatter...................287Solid-StateElectronics..............559Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Chapter14Chapter30VibrationsandWaves..............311NuclearPhysics...................573Chapter15AppendixBSound...........................329AdditionalProblems...............591Chapter16FundamentalsofLight.............345Physics:PrinciplesandProblemsContentsiii
3TotheTeacherTheSolutionsManualisacomprehensiveguidetothequestionsandproblemsintheStudentEditionofPhysics:PrinciplesandProblems.ThisincludesthePracticeProblems,SectionReviews,ChapterAssessments,andChallengeProblemsforeachchapter,aswellastheAdditionalProblemsthatappearinAppendixBoftheStudentEdition.TheSolutionsManualrestateseveryquestionandproblemsothatyoudonothavetolookbackatthetextwhenreviewingproblemswithstudents.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ivTotheTeacherPhysics:PrinciplesandProblems
4CHAPTER1APhysicsToolkit6.Convert5021centimeterstokilometers.PracticeProblems1m1km5021cm���������1.1MathematicsandPhysics100cm1000mpages3–105.021�10�2kmpage57.Howmanysecondsareinaleapyear?Foreachproblem,givetherewrittenequationyouwoulduseandtheanswer.24h60min60s366days�������������1day1h1min1.Alightbulbwitharesistanceof50.0ohms31,622,400sisusedinacircuitwitha9.0-voltbattery.Whatisthecurrentthroughthebulb?8.Convertthespeed5.30m/stokm/h.V9.0voltI�������0.18ampere5.30m60s60min1kmR50.0ohms�����������������1s1min1h1000m2.Anobjectwithuniformaccelerationa,19.08km/hstartingfromrest,willreachaspeedofvintimetaccordingtotheformulav�at.page8WhatistheaccelerationofabicyclistwhoSolvethefollowingproblems.acceleratesfromrestto7m/sin4s?9.a.6.201cm�7.4cm�0.68cm�v7m/s2a�������1.75m/s12.0cmt4s6.201cm3.Howlongwillittakeascooteraccelerating7.4cmat0.400m/s2togofromresttoaspeedof0.68cm4.00m/s?�12.0cmv4.00m/s26.281cmt�������10.0sa0.400m/s2�26.3cmafterroundingb.1.6km�1.62m�1200cm4.Thepressureonasurfaceisequaltotheforcedividedbythearea:P�F/A.1.6km�1600mA53-kgwomanexertsaforce(weight)of1.62m�1.62m520Newtons.Ifthepressureexertedon1200cm��12mtheflooris32,500N/m2,whatisthearea1613.62mofthesolesofhershoes?�1600mor1.6kmafterroundingF520N2A�������0.016mP32,500N/m210.a.10.8g�8.264g10.8g�8.264gpage7Usedimensionalanalysistocheckyourequation2.536gCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.beforemultiplying.�2.5gafterrounding5.Howmanymegahertzis750kilohertz?1000Hz1MHz750kHz���������1kHz1,000,000Hz0.75MHzPhysics:PrinciplesandProblemsSolutionsManual1
5Chapter1continuedb.4.75m�0.4168ma.Substitutethevaluesintotheequationyouwilluse.Aretheunitscorrect?4.75m�0.4168mF�Bqv4.3332m�(4.5kg/A�s2)(1.60�10�19A�s)�4.33mafterrounding(2.4�105m/s)11.a.139cm�2.3cmForcewillbemeasuredinkg�m/s2,320cm2or3.2�102cm2whichiscorrect.b.Thevaluesarewritteninscientificb.3.2145km�4.23kmnotation,m�10n.Calculatethe10npart13.6km2oftheequationtoestimatethesizeoftheanswer.12.a.13.78g�11.3mL10�19�105�10�14;theanswerwill1.22g/mLbeabout20�10�14,or2�10�13.b.18.21g�4.4cm3c.Calculateyouranswer.Checkitagainst4.1g/cm3yourestimatefrompartb.1.7�10�13kg�m/s2SectionReviewd.Justifythenumberofsignificantdigitsinyouranswer.1.1MathematicsandPhysicsTheleast-precisevalueis4.5T,withpages3–102significantdigits,sotheanswerispage10roundedto2significantdigits.13.MathWhyareconceptsinphysicsdescribedwithformulas?16.MagnetismRewriteF�BqvtofindvintermsofF,q,andB.Theformulasareconciseandcanbeusedtopredictnewdata.Fv���Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Bq14.MagnetismTheforceofamagneticfield17.CriticalThinkingAnacceptedvalueforonacharged,movingparticleisgivenbytheaccelerationduetogravityis9.801m/s2.F�Bqv,whereFistheforceinkg�m/s2,qisInanexperimentwithpendulums,youthechargeinA�s,andvisthespeedinm/s.calculatethatthevalueis9.4m/s2.ShouldBisthestrengthofthemagneticfield,theacceptedvaluebetossedouttoaccom-measuredinteslas,T.Whatis1teslamodateyournewfinding?Explain.describedinbaseunits?2hasbeenNo.Thevalue9.801m/sF�Bqv,soB�F�establishedbymanyotherexperiments,�qvandtodiscardthefindingyouwouldkg�m/s2kghavetoexplainwhytheywerewrong.T������(A�s)(m/s)A�s2Thereareprobablysomefactorsaffectingyourcalculation,suchas1T�1kg/A�s2frictionandhowpreciselyyoucanmeasurethedifferentvariables.15.MagnetismAprotonwithcharge1.60�10�19A�sismovingat2.4�105m/sthroughamagneticfieldof4.5T.Youwanttofindtheforceontheproton.2SolutionsManualPhysics:PrinciplesandProblems
6Chapter1continuedd.HowpreciseisthemeasureoftheSectionReviewheightofonebox?Of12boxes?1.2Measurementnearesttenthofacm;nearesttenthpages11–14ofacmpage1423.CriticalThinkingYourfriendstatesina18.AccuracySomewoodenrulersdonotstartreportthattheaveragetimerequiredtowith0attheedge,buthaveitsetinafewcirclea1.5-mitrackwas65.414s.Thiswasmillimeters.Howcouldthisimprovethemeasuredbytiming7lapsusingaclockaccuracyoftheruler?withaprecisionof0.1s.HowmuchAstheedgeoftherulergetswornawayconfidencedoyouhaveintheresultsofovertime,thefirstmillimeterortwoofthereport?Explain.thescalewouldalsobewornawayifAresultcanneverbemoreprecisethanthescalestartedattheedge.theleastprecisemeasurement.The19.ToolsYoufindamicrometer(atoolusedcalculatedaveragelaptimeexceedstomeasureobjectstothenearest0.01mm)theprecisionpossiblewiththeclock.thathasbeenbadlybent.Howwoulditcomparetoanew,high-qualitymeterstickintermsofitsprecision?Itsaccuracy?PracticeProblemsItwouldbemoreprecisebutless1.3GraphingDataaccurate.pages15–19page1820.ParallaxDoesparallaxaffecttheprecision24.Themassvaluesofspecifiedvolumesofofameasurementthatyoumake?Explain.puregoldnuggetsaregiveninTable1-4.No,itdoesn’tchangethefinenessofthedivisionsonitsscale.Table1-4MassofPureGoldNuggets21.ErrorYourfriendtellsyouthathisheightis182cm.Inyourownwords,explaintheVolume(cm3)Mass(g)rangeofheightsimpliedbythisstatement.1.019.4Hisheightwouldbebetween181.5and2.038.6182.5cm.Precisionofameasurement3.058.1isone-halfthesmallestdivisionontheinstrument.Theheight182cmwould4.077.4range�0.5cm.5.096.5a.Plotmassversusvolumefromthe22.PrecisionAboxhasalengthof18.1cmandvaluesgiveninthetableanddrawawidthof19.2cm,anditis20.3cmtall.thecurvethatbestfitsallpoints.a.Whatisitsvolume?7.05�103cm3100b.Howpreciseisthemeasureoflength?80Ofvolume?60Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.nearesttenthofacm;nearestMass(g)4010cm320c.Howtallisastackof12oftheseboxes?012345243.6cmVolume(cm3)Physics:PrinciplesandProblemsSolutionsManual3
7Chapter1continuedb.Describetheresultingcurve.27.PredictUsetherelationillustratedinastraightlineFigure1-16todeterminethemassrequiredtostretchthespring15cm.c.Accordingtothegraph,whattypeofrelationshipexistsbetweenthemassof16gthepuregoldnuggetsandtheirvolume?28.PredictUsetherelationinFigure1-18toTherelationshipislinear.predictthecurrentwhentheresistanceisd.Whatisthevalueoftheslopeofthis16ohms.graph?Includetheproperunits.7.5A�y96.5g�19.4gslope��������x5.0cm3�1.0cm329.CriticalThinkingInyourownwords,3explainthemeaningofashallowerline,or�19.3g/cmasmallerslopethantheoneinFigure1-16,e.Writetheequationshowingmassasainthegraphofstretchversustotalmassforfunctionofvolumeforgold.adifferentspring.m�(19.3g/cm3)VThespringwhoselinehasasmallerf.Writeawordinterpretationfortheslopeslopeisstiffer,andthereforerequiresoftheline.moremasstostretchitonecentimeter.Themassforeachcubiccentimeterofpuregoldis19.3g.ChapterAssessmentConceptMappingSectionReviewpage241.3GraphingData30.Completethefollowingconceptmapusingpages15–19thefollowingterms:hypothesis,graph,mathematicalmodel,dependentvariable,page19measurement.25.MakeaGraphGraphthefollowingdata.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Timeistheindependentvariable.hypothesisTime(s)05101520253035Speed(m/s)1210864222experiment128measurementSpeed(m/s)4dependentindependent010203040variablevariableTime(s)26.InterpretaGraphWhatwouldbethegraphmeaningofanonzeroy-intercepttoagraphoftotalmassversusvolume?Thereisanonzerototalmasswhenthemathematicalvolumeofthematerialiszero.Thismodelcouldhappenifthemassvalueincludesthematerial’scontainer.4SolutionsManualPhysics:PrinciplesandProblems
8Chapter1continuedMasteringConcepts1b.�m1000page2431.Describeascientificmethod.(1.1)millimeterIdentifyaproblem;gatherinformationc.1000maboutitbyobservingandexperimenting;kilometeranalyzetheinformationtoarriveatananswer.37.Toconvert1.8htominutes,bywhatconversionfactorshouldyoumultiply?(1.1)32.Whyismathematicsimportanttoscience?60min��,becausetheunitswillcancel(1.1)1hMathematicsallowsyoutobequantita-correctly.tive,tosay“howfast,”notjust“fast.”38.Solveeachproblem.Givethecorrectnumber33.WhatistheSIsystem?(1.1)ofsignificantdigitsintheanswers.(1.1)TheInternationalSystemofUnits,orSI,a.4.667�104g�3.02�105gisabase10systemofmeasurement3.49�105gthatisthestandardinscience.Thebaseb.(1.70�102J)�(5.922�10�4cm3)unitsarethemeter,kilogram,second,2.87�105J/cm3kelvin,mole,ampere,andcandela.39.Whatdeterminestheprecisionofa34.Howarebaseunitsandderivedunitsmeasurement?(1.2)related?(1.1)theprecisionofameasuringdevice,Thederivedunitsarecombinationsofwhichislimitedbythefinestdivisionthebaseunits.onitsscale35.Supposeyourlabpartnerrecordeda40.Howdoesthelastdigitdifferfromthemeasurementas100g.(1.1)otherdigitsinameasurement?(1.2)a.WhyisitdifficulttotellthenumberofThefinaldigitisestimated.significantdigitsinthismeasurement?Zerosarenecessarytoindicatethe41.Acar’sodometermeasuresthedistancemagnitudeofthevalue,butthereisfromhometoschoolas3.9km.Usingnowayofknowingwhetherornotthestringonamap,youfindthedistancetobeinstrumentusedtomeasuretheval-4.2km.Whichanswerdoyouthinkismoreuesactuallymeasuredthezeros.Theaccurate?Whatdoesaccuratemean?(1.2)zerosmayserveonlytolocatethe1.Themostaccuratemeasureistheb.Howcanthenumberofsignificantmeasureclosesttotheactualdistance.digitsinsuchanumberbemadeclear?TheodometerisprobablymoreWritethenumberinscientificaccurateasitactuallycoveredthenotation,includingonlythedistance.Themapisamodelmadesignificantdigits.frommeasurements,soyourmeasure-mentsfromthemaparemoreremoved36.Givethenameforeachofthefollowingfromtherealdistance.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.multiplesofthemeter.(1.1)142.Howdoyoufindtheslopeofalineara.�m100graph?(1.3)centimeterTheslopeofalineargraphistheratiooftheverticalchangetothehorizontalchange,orriseoverrun.Physics:PrinciplesandProblemsSolutionsManual5
9Chapter1continued43.Foradriver,thetimebetweenseeinga46.GiventheequationF�mv2/R,whatstoplightandsteppingonthebrakesisrelationshipexistsbetweeneachofthecalledreactiontime.Thedistancetraveledfollowing?(1.3)duringthistimeisthereactiondistance.a.FandRReactiondistanceforagivendriverandinverserelationshipvehicledependslinearlyonspeed.(1.3)b.Fandma.Wouldthegraphofreactiondistanceversusspeedhaveapositiveoralinearrelationshipnegativeslope?c.FandvPositive.Asspeedincreases,quadraticrelationshipreactiondistanceincreases.b.AdriverwhoisdistractedhasalongerApplyingConceptsreactiontimethanadriverwhoisnot.pages25–26Wouldthegraphofreactiondistance47.Figure1-21givestheheightabovetheversusspeedforadistracteddriverhavegroundofaballthatisthrownupwardalargerorsmallerslopethanforafromtheroofofabuilding,forthefirstnormaldriver?Explain.1.5sofitstrajectory.Whatistheball’sLarger.Thedriverwhowasdistractedheightatt�0?Predicttheball’sheightatwouldhavealongerreactiontimet�2sandatt�5s.andthusagreaterreactiondistanceHeightofBallv.Timeatagivenspeed.44.Duringalaboratoryexperiment,the25temperatureofthegasinaballoonisvaried20andthevolumeoftheballoonismeasured.Whichquantityistheindependent15variable?WhichquantityisthedependentHeight(m)10variable?(1.3)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Temperatureistheindependentvari-5able;volumeisthedependentvariable.0123445.WhattypeofrelationshipisshowninTime(s)Figure1-20?Givethegeneralequationfor■Figure1-21thistypeofrelation.(1.3)Whent�0andt�2,theball’sheightywillbeabout20m.Whent�5,theballwillhavelandedonthegroundsotheheightwillbe0m.48.Isascientificmethodonesetofclearlydefinedsteps?Supportyouranswer.Thereisnodefiniteorderofspecificsteps.However,whateverapproachxisused,italwaysincludescloseobservation,controlledexperimentation,■Figure1-20summarizing,checking,andrechecking.quadratic;y�ax2�bx�c6SolutionsManualPhysics:PrinciplesandProblems
10Chapter1continued49.ExplainthedifferencebetweenascientificStates.Findasmanyveryshortandverytheoryandascientificlaw.longexamplesasyoucan.Ascientificlawisaruleofnature,wheresampleanswer:ascientifictheoryisanexplanationofhalf-lifeofpolonium-194,0.7s;thescientificlawbasedonobservation.timebetweenheartbeats,0.8s;timetoAtheoryexplainswhysomethinghap-walkbetweenphysicsclassandmathpens;alawdescribeswhathappens.class,2.4min;lengthofschoolyear,180days;timebetweenelectionsfor50.DensityThedensityofasubstanceisitstheU.S.HouseofRepresentatives,massperunitvolume.2years;timebetweenU.S.presidentiala.Giveapossiblemetricunitfordensity.elections,4years;ageoftheUnitedpossibleanswersincludeg/cm3orStates,(about)230yearskg/m354.SpeedofLightTwostudentsmeasureb.Istheunitfordensityabaseunitorathespeedoflight.Oneobtainsderivedunit?(3.0010.001)�108m/s;theotherobtainsderivedunit(2.9990.006)�108m/s.a.Whichismoreprecise?51.Whatmetricunitwouldyouusetomeasure(3.001�0.001)�108m/seachofthefollowing?b.Whichismoreaccurate?a.thewidthofyourhand(2.999�0.006)�108m/scmb.thethicknessofabookcover55.Youmeasurethedimensionsofadeskasmm132cm,83cm,and76cm.Thesumofc.theheightofyourclassroomthesemeasuresis291cm,whiletheproductis8.3�105cm3.Explainhowthesignificantmdigitsweredeterminedineachcase.d.thedistancefromyourhometoyourInadditionandsubtraction,youaskclassroomwhatplacetheleastprecisemeasureiskmknownto:inthiscase,tothenearestcm.Sotheanswerisroundedtothe52.SizeMakeachartofsizesofobjects.nearestcm.InmultiplicationandLengthsshouldrangefromlessthan1mmdivision,youlookatthenumberoftoseveralkilometers.Samplesmightsignificantdigitsintheleastpreciseincludethesizeofacell,thedistancelightanswer:inthiscase,2.Sotheansweristravelsin1s,andtheheightofaroom.roundedto2significantdigits.sampleanswer:radiusoftheatom,5�10�11m;virus,56.MoneySupposeyoureceive$5.00atthe10�7m;thicknessofpaper,0.1mm;beginningofaweekandspend$1.00eachwidthofpaperbackbook,10.7cm;dayforlunch.Youprepareagraphoftheheightofadoor,1.8m;widthoftown,amountyouhaveleftattheendofeachday7.8km;radiusofEarth,6�106m;foroneweek.WouldtheslopeofthisgraphdistancetotheMoon,4�108mbepositive,zero,ornegative?Why?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.negative,becausethechangein53.TimeMakeachartoftimeintervals.verticaldistanceisnegativeforaSampleintervalsmightincludethetimepositivechangeinhorizontaldistancebetweenheartbeats,thetimebetweenpresidentialelections,theaveragelifetimeofahuman,andtheageoftheUnitedPhysics:PrinciplesandProblemsSolutionsManual7
11Chapter1continued57.Dataareplottedonagraph,andthevaluec.Whatisthenumberofsignificantdigitsonthey-axisisthesameforeachvalueofforthetotalmass?theindependentvariable.Whatisthefourslope?Why?Howdoesydependonx?d.WhyisthenumberofsignificantdigitsZero.Thechangeinverticaldistanceisdifferentforthetotalmassandthezero.ydoesnotdependonx.individualmasses?Whenaddingmeasurements,the58.DrivingThegraphofbrakingdistanceprecisionmatters:bothmassesareversuscarspeedispartofaparabola.Thus,theequationiswrittend�av2�bv�c.knowntothenearesthundredthofagram,sothetotalshouldbegiventoThedistance,d,hasunitsinmeters,andthenearesthundredthofagram.velocity,v,hasunitsinmeters/second.SignificantdigitssometimesareHowcouldyoufindtheunitsofa,b,andc?gainedwhenadding.Whatwouldtheybe?Theunitsineachtermoftheequation61.HistoryAristotlesaidthatthespeedofamustbeinmetersbecausedistance,d,fallingobjectvariesinverselywiththedensityismeasuredinmeters.ofthemediumthroughwhichitfalls.av2�a(m/s)2,soaisins2/m;a.AccordingtoAristotle,wouldarockfallbv�b(m/s),sobisins�1.fasterinwater(density1000kg/m3),orinair(density1kg/m3)?59.HowlongistheleafinFigure1-22?Lowerdensitymeansfasterspeed,Includetheuncertaintyinyoursotherockfallsfasterinair.measurement.b.Howfastwouldarockfallinavacuum?Basedonthis,whywouldAristotlesaythattherecouldbenosuchthingasavacuum?BecauseavacuumwouldhaveaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.zerodensity,therockshouldfallinfinitelyfast.Nothingcanfallthatfast.62.Explainthedifferencebetweenahypothesis■Figure1-22andascientifictheory.8.3cm�0.05cm,or83mm�0.5mmAscientifictheoryhasbeentestedandsupportedmanytimesbeforeit60.Themassesoftwometalblocksarebecomesaccepted.Ahypothesisisanmeasured.BlockAhasamassof8.45gideaabouthowthingsmightwork—itandblockBhasamassof45.87g.hasmuchlesssupport.a.Howmanysignificantdigitsare63.Giveanexampleofascientificlaw.expressedinthesemeasurements?Newton’slawsofmotion,lawofconser-A:three;B:fourvationofenergy,lawofconservationofb.WhatisthetotalmassofblockApluscharge,lawofreflectionblockB?54.32g8SolutionsManualPhysics:PrinciplesandProblems
12Chapter1continued64.WhatreasonmighttheancientGreeks68.Addorsubtractasindicated.havehadnottoquestionthehypothesisa.5.80�109s�3.20�108sthatheavierobjectsfallfasterthanlighter9s6.12�10objects?Hint:Didyoueverquestionwhichb.4.87�10�6m�1.93�10�6mfallsfaster?2.94�10�6mAirresistanceaffectsmanylightobjects.Withoutcontrolledexperi-c.3.14�10�5kg�9.36�10�5kgments,theireverydayobservationstold1.250�10�4kgthemthatheavierobjectsdidfallfaster.d.8.12�107g�6.20�106g7.50�107g65.MarsExplainwhatobservationsledtochangesinscientists’ideasaboutthesurface69.RankthefollowingmassmeasurementsofMars.fromleasttogreatest:11.6mg,1021�g,Astelescopesimprovedandlater0.000006kg,0.31mg.probesweresentintospace,scientists0.31mg,1021µg,0.000006kg,11.6mggainedmoreinformationaboutthesurface.Whentheinformationdid70.Statethenumberofsignificantdigitsinnotsupportoldhypotheses,theeachofthefollowingmeasurements.hypotheseschanged.a.0.00003m66.AgraduatedcylinderismarkedeverymL.1Howpreciseameasurementcanyoumakeb.64.01fmwiththisinstrument?4�0.5mLc.80.001mMasteringProblems5d.0.720�gpages26–281.1MathematicsandPhysics367.Converteachofthefollowinge.2.40�106kgmeasurementstometers.3a.42.3cmf.6�108kg0.423m1b.6.2pmg.4.07�1016m6.2�10�12m3c.21km2.1�104m71.Addorsubtractasindicated.a.16.2m�5.008m�13.48md.0.023mm2.3�10�5m34.7mb.5.006m�12.0077m�8.0084me.214�m2.14�10�4m25.022mc.78.05cm2�32.046cm2f.57nmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.46.00cm25.7�10�8md.15.07kg�12.0kg3.1kgPhysics:PrinciplesandProblemsSolutionsManual9
13Chapter1continued72.Multiplyordivideasindicated.78.Howpreciseameasurementcouldyoua.(6.2�1018m)(4.7�10�10m)makewiththescaleshowninFigure1-23?2.9�109m2b.(5.6�10�7m)/(2.8�10�12s)2.0�105m/sc.(8.1�10�4km)(1.6�10�3km)1.3�10�6km2d.(6.5�105kg)/(3.4�103m3)1.9�102kg/m373.GravityTheforceduetogravityisF�mgwhereg�9.80m/s2.■Figure1-23a.Findtheforceduetogravityona�0.5g41.63-kgobject.408kg�m/s279.GivethemeasureshownonthemeterinFigure1-24aspreciselyasyoucan.Includeb.Theforceduetogravityonanobjectis632kg�m/s2.Whatisitsmass?theuncertaintyinyouranswer.64.5kg231474.DimensionalAnalysisPressureismea-suredinpascals,where1Pa�1kg/m�s2.5A0WillthefollowingexpressiongiveaACLASSApressureinthecorrectunits?(0.55kg)(2.1m/s)���9.8m/s23Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.No;itisinkg/s1.2Measurement■Figure1-2475.Awatertankhasamassof3.64kgwhenit3.6�0.1Aisemptyandamassof51.8kgwhenitisfilledtoacertainlevel.Whatisthemassof80.Estimatetheheightofthenearestdoorthewaterinthetank?frameincentimeters.Thenmeasureit.48.2kgHowaccuratewasyourestimate?Howprecisewasyourestimate?Howprecise76.Thelengthofaroomis16.40m,itswidthwasyourmeasurement?Whyarethetwois4.5m,anditsheightis3.26m.Whatprecisionsdifferent?volumedoestheroomenclose?Astandardresidentialdoorframeheight2.4�102m3is80inches,whichisabout200cm.Theprecisiondependsonthemeasurement77.Thesidesofaquadrangularplotoflandinstrumentused.are132.68m,48.3m,132.736m,and48.37m.Whatistheperimeteroftheplot?362.1m10SolutionsManualPhysics:PrinciplesandProblems
14Chapter1continued81.BaseUnitsGivesixexamplesofquantitiesMassofyoumightmeasureinaphysicslab.IncludeThreeSubstancestheunitsyouwoulduse.800Sample:distance,cm;volume,mL;700mass,g;current,A;time,s;600temperature,°CC50082.TemperatureThetemperaturedropsfrom400Mass(g)B24°Cto10°Cin12hours.300200a.Findtheaveragetemperaturechangeper100hour.A1.2°C/h01020304050b.Predictthetemperaturein2morehoursVolume(cm3)ifthetrendcontinues.■Figure1-258°C84.Duringaclassdemonstration,aphysicsc.Couldyouaccuratelypredicttheinstructorplacedamassonahorizontaltemperaturein24hours?tablethatwasnearlyfrictionless.TheNo.Temperatureisunlikelytocon-instructorthenappliedvarioushorizontaltinuefallingsharplyandsteadilyforcestothemassandmeasuredthethatlong.distanceittraveledin5secondsforeachforceapplied.TheresultsoftheexperimentareshowninTable1-5.1.3GraphingData83.Figure1-25showsthemassesofthreeTable1-5substancesforvolumesbetween0and60cm3.DistanceTraveledwithDifferentForcesa.Whatisthemassof30cm3ofeachForce(N)Distance(cm)substance?5.024(a)80g,(b)260g,(c)400g10.049b.Ifyouhad100gofeachsubstance,whatwouldbetheirvolumes?15.075(a)36cm3,(b)11cm3,(c)7cm320.099c.Inoneortwosentences,describethe25.0120meaningoftheslopesofthelinesin30.0145thisgraph.Thesloperepresentstheincreaseda.Plotthevaluesgiveninthetableandmassofeachadditionalcubicdrawthecurvethatbestfitsallpoints.centimeterofthesubstance.160d.Whatisthey-interceptofeachline?120Whatdoesitmean?They-interceptis(0,0).Itmeansthat803,thereisnoneoftheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.whenV�0cmDistance(cm)40substancepresent(m�0g).0.010.020.030.0Force(N)Physics:PrinciplesandProblemsSolutionsManual11
15Chapter1continuedb.Describetheresultingcurve.b.Describetheresultingcurve.astraightlineahyperbolac.Usethegraphtowriteanequationc.Accordingtothegraph,whatistherelatingthedistancetotheforce.relationshipbetweenmassandthed�4.9Faccelerationproducedbyaconstantforce?d.Whatistheconstantintheequation?Finditsunits.Accelerationvariesinverselywithmass.Theconstantis4.9andhasunitscm/N.d.Writetheequationrelatingaccelerationtomassgivenbythedatainthegraph.e.Predictthedistancetraveledwhena22.0-Nforceisexertedontheobject12a���mfor5s.e.Findtheunitsoftheconstantinthe108cmor110cmusing2significantequation.digits2kg�m/s85.Thephysicsinstructorfromthepreviousf.Predicttheaccelerationofan8.0-kgproblemchangedtheprocedure.Themassmass.wasvariedwhiletheforcewaskeptcon-1.5m/s2stant.Timeanddistanceweremeasured,andtheaccelerationofeachmasswascal-86.Duringanexperiment,astudentmeasuredculated.Theresultsoftheexperimentarethemassof10.0cm3ofalcohol.ThestudentshowninTable1-6.thenmeasuredthemassof20.0cm3ofalcohol.Inthisway,thedatainTable1-7Table1-6werecollected.AccelerationofDifferentMassesTable1-7Mass(kg)Acceleration(m/s2)TheMassValuesof1.012.0SpecificVolumesofAlcoholCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2.05.9Volume(cm3)Mass(g)3.04.110.07.94.03.020.015.85.02.530.023.76.02.040.031.650.039.6a.Plotthevaluesgiveninthetableanddrawthecurvethatbestfitsallpoints.a.Plotthevaluesgiveninthetableand)12.0drawthecurvethatbestfitsallthepoints.240.09.030.06.020.0Mass(g)3.0Acceleration(m/s10.00.02.04.06.00.0Mass(kg)10.020.030.040.050.060.0Volume(cm3)12SolutionsManualPhysics:PrinciplesandProblems
16Chapter1continuedb.Describetheresultingcurve.90.Youaregiventhefollowingmeasurementsastraightlineofarectangularbar:length�2.347m,thickness�3.452cm,height�2.31mm,c.Usethegraphtowriteanequationmass�1659g.Determinethevolume,inrelatingthevolumetothemassofthecubicmeters,anddensity,ing/cm3,ofthealcohol.beam.Expressyourresultsinproperform.m�0.79Vvolume�1.87�10�4m3,or187cm3;d.Findtheunitsoftheslopeofthegraph.3density�8.87g/cmWhatisthenamegiventothisquantity?g/cm3;density91.Adropofwatercontains1.7�1021mole-e.Whatisthemassof32.5cm3ofcules.Ifthewaterevaporatedattherateofalcohol?onemillionmoleculespersecond,howmanyyearswouldittakeforthedropto25.7gcompletelyevaporate?MixedReview1.7�1021molecules�1.7�1015spage28�����1,000,000molecules1s87.Arrangethefollowingnumbersfrommost15s)1h1day1yprecisetoleastprecise(1.7�10�������������3600s24h365days0.0034m45.6m1234m5.4�107y0.0034m,45.6m,1234m92.A17.6-gramsampleofmetalisplacedina88.Figure1-26showsthetoroidal(doughnut-3ofgraduatedcylindercontaining10.0cmshaped)interiorofthenow-dismantled3,water.Ifthewaterlevelrisesto12.20cmTokamakFusionTestReactor.Explainwhyawhatisthedensityofthemetal?widthof80mwouldbeanunreasonablemvalueforthewidthofthetoroid.Whatdensity���Vwouldbeareasonablevalue?17.6g����12.20cm3�10.0cm3�8.00g/cm3ThinkingCriticallypage2893.ApplyConceptsIthasbeensaidthatfoolscanaskmorequestionsthanthewisecananswer.Inscience,itisfrequentlythecasethatonewisepersonisneededtoasktherightquestionratherthantoanswerit.■Figure1-26Explain.80metersisequivalenttoabout260feet,The“right”questionisonethatpointswhichwouldbeverylarge.10meterstofruitfulresearchandtootherwouldbeamorereasonablevalue.questionsthatcanbeanswered.89.Youarecrackingacodeandhave94.ApplyConceptsFindtheapproximatemassCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.discoveredthefollowingconversionofwaterinkilogramsneededtofillacon-factors:1.23longs�23.0mediums,andtainerthatis1.40mlongand0.600mwide74.5mediums�645shorts.Howmanytoadepthof34.0cm.Reportyourresulttoshortsareequaltoonelong?onesignificantdigit.(Useareferencesource23.0med645shorttofindthedensityofwater.)1long���������162shorts1.23long74.5medPhysics:PrinciplesandProblemsSolutionsManual13
17Chapter1continuedV99.Explainhowimprovedprecisioninw�(140cm)(60.0cm)(34.0cm)�285,600cm3.Becausethedensityofmeasuringtimewouldhaveledtowateris1.00g/cm3,themassofwatermoreaccuratepredictionsabouthowinkilogramsis286kg.anobjectfalls.Answerswillvary.Forexample,students95.AnalyzeandConcludeAcontainerofgasmightsuggestthatimprovedprecisionwithapressureof101kPahasavolumecanleadtobetterobservations.of324cm3andamassof4.00g.Ifthepressureisincreasedto404kPa,whatisthedensityofthegas?PressureandvolumeChallengeProblemareinverselyproportional.page17PressureandvolumeareinverselyAnobjectissuspendedfromspring1,andtheproportional.Sincethepressureis1spring’selongation(thedistanceitstretches)isX1.4timesgreater,thevolumewillbe��4Thenthesameobjectisremovedfromthefirstoftheoriginalvolume.springandsuspendedfromasecondspring.The324cm33elongationofspring2isX���81.0cm2.X2isgreaterthanX1.41.Onthesameaxes,sketchthegraphsofthe4.00g���0.0494g/cm3massversuselongationforbothsprings.81.0cm396.DesignanExperimentHowhighcanyouthrowaball?Whatvariablesmightaffecttheanswertothisquestion?X2massofball,footing,practice,andXconditioningX197.CalculateIftheSunsuddenlyceasedtoshine,howlongwouldittakeEarthtoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.becomedark?(YouwillhavetolookuptheFspeedoflightinavacuumandthedistancefromtheSuntoEarth.)Howlongwouldit2.Istheoriginincludedinthegraph?WhyortakethesurfaceofJupitertobecomedark?whynot?dE1.496�1011mYes;theorigincorrespondstot�����E�v3.00�108m/s0elongationwhentheforceis0.�499s�8.31min3.Whichslopeissteeper?dJ7.78�1011mt�����J�v3.00�108m/sTheslopeforX2issteeper.�2593s�43.2min4.Atagivenmass,X2�1.6X1.IfXWritinginPhysics2�5.3cm,whatisX1?Xpage282�1.6X198.Researchanddescribeatopicinthehistory5.3cm�1.6X1ofphysics.Explainhowideasaboutthe3.3cm�X1topicchangedovertime.Besuretoincludethecontributionsofscientistsandtoevaluatetheimpactoftheircontributionsonscientificthoughtandtheworldoutsidethelaboratory.Answerswillvary.14SolutionsManualPhysics:PrinciplesandProblems
18CHAPTER2RepresentingMotion4.CriticalThinkingUsetheparticlemodelSectionReviewtodrawmotiondiagramsfortworunners2.1PicturingMotioninarace,whenthefirstrunnercrossesthepages31–33finishlineastheotherrunneristhree-fourthsofthewaytothefinishline.page331.MotionDiagramofaRunnerUsetheRunner2t0t1t2t3t4particlemodeltodrawamotiondiagramforabikeriderridingataconstantpace.Runner1t0t1t2t3t4StartFinish2.MotionDiagramofaBirdUsetheparti-clemodeltodrawasimplifiedmotiondia-SectionReviewgramcorrespondingtothemotiondiagraminFigure2-4foraflyingbird.Whatpoint2.2WhereandWhen?onthebirddidyouchoosetorepresentit?pages34–37page375.DisplacementTheparticlemodelforacartravelingonaninterstatehighwayisshownbelow.Thestartingpointisshown.HereThereMakeacopyoftheparticlemodel,anddrawavectortorepresentthedisplacement■Figure2-4ofthecarfromthestartingtimetotheend3.MotionDiagramofaCarUsetheparticleofthethirdtimeinterval.modeltodrawasimplifiedmotiondiagramHereTherecorrespondingtothemotiondiagraminFigure2-5foracarcomingtoastopata6.DisplacementTheparticlemodelforaboystopsign.Whatpointonthecardidyouwalkingtoschoolisshownbelow.usetorepresentit?HomeSchoolMakeacopyoftheparticlemodel,anddrawvectorstorepresentthedisplacementbetweeneachpairofdots.HomeSchool■Figure2-5Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual15
19Chapter2continued7.PositionTwostudentscomparedthePracticeProblemspositionvectorstheyeachhaddrawnonamotiondiagramtoshowthepositionofa2.3Position-TimeGraphsmovingobjectatthesametime.Theyfoundpages38–42thattheirvectorsdidnotpointinthesamepage39direction.Explain.Forproblems9–11,refertoFigure2-13.Apositionvectorgoesfromtheorigintotheobject.Whentheoriginsaredif-150.0ferent,thepositionvectorsaredifferent.Ontheotherhand,adisplacementvec-100.0torhasnothingtodowiththeorigin.50.08.CriticalThinkingAcartravelsstraightPosition(m)0.0alongthestreetfromthegrocerystoreto1.03.05.07.0thepostoffice.Torepresentitsmotionyou�50.0Time(s)useacoordinatesystemwithitsoriginatthegrocerystoreandthedirectionthecaris■Figure2-13movinginasthepositivedirection.Your9.Describethemotionofthecarshownbyfriendusesacoordinatesystemwithitsori-thegraph.ginatthepostofficeandtheoppositeThecarbeginsatapositionof125.0mdirectionasthepositivedirection.Wouldandmovestowardtheorigin,arrivingatthetwoofyouagreeonthecar’sposition?theorigin5.0safteritbeginsmoving.Displacement?Distance?ThetimeintervalThecarcontinuesbeyondtheorigin.thetriptook?Explain.Thetwostudentsshouldagreeonthe10.Drawamotiondiagramthatcorrespondstodisplacement,distance,andtimeintervalthegraph.forthetrip,becausethesethreequanti-tiesareindependentofwheretheorigint0�0.0st5�5.0sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofthecoordinatesystemisplaced.Thetwostudentswouldnotagreeonthe125.0m0.0mcar’sposition,becausethepositionisdmeasuredfromtheoriginofthecoordi-natesystemtothelocationofthecar.11.Answerthefollowingquestionsaboutthecar’smotion.Assumethatthepositived-directioniseastandthenegatived-directioniswest.a.Whenwasthecar25.0meastoftheorigin?at4.0sb.Wherewasthecarat1.0s?100.0m12.Describe,inwords,themotionofthetwopedestriansshownbythelinesinFigure2-14.Assumethatthepositivedirec-tioniseastonBroadStreetandtheoriginistheintersectionofBroadandHighStreets.16SolutionsManualPhysics:PrinciplesandProblems
20Chapter2continuedBroadSt.page41Forproblems14–17,refertothefigureinEastExampleProblem2.200.0A150.0100.0Position(m)HighSt.50.0BPosition(m)0.02.04.06.08.010.012.0WestTime(s)Time(s)■Figure2-14■ExampleProblem2FigurePedestrianAstartswestofHighStreet14.Whateventoccurredatt�0.0s?andwalkseast(thepositivedirection).RunnerApassedtheorigin.PedestrianBbeginseastofHighStreetandwalkswest(thenegativedirection).15.Whichrunnerwasaheadatt�48.0s?SometimeafterBcrossesHighStreet,runnerBAandBpasseachother.Sometimeaftertheypass,PedestrianAcrosses16.WhenrunnerAwasat0.0m,wherewasHighStreet.runnerB?at�50.0m13.Odinawalkeddownthehallatschoolfromthecafeteriatothebandroom,a17.HowfarapartwererunnersAandBatdistanceof100.0m.Aclassofphysicst�20.0s?studentsrecordedandgraphedherapproximately30mpositionevery2.0s,notingthatshemoved2.6mevery2.0s.WhenwasOdinainthe18.Juanitagoesforawalk.Sometimelater,herfollowingpositions?friendHeatherstartstowalkafterher.Theira.25.0mfromthecafeteriamotionsarerepresentedbytheposition-19stimegraphsinFigure2-16.b.25.0mfromthebandroom6.058s5.0ac.CreateagraphshowingOdina’sit4.0anmotion.Jur3.0eathe100.0H2.080.0Position(km)1.060.040.00.00.51.01.52.0Distancefromcafeteria(m)20.0Time(h)0.0010.030.050.070.0■Figure2-16Time(s)a.HowlonghadJuanitabeenwalkingCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.whenHeatherstartedherwalk?6.0minPhysics:PrinciplesandProblemsSolutionsManual17
21Chapter2continuedb.WillHeathercatchuptoJuanita?Howt0�0.0st7�7.0scanyoutell?No.ThelinesrepresentingJuanita’sandHeather’smotionsgetfarther0m140mapartastimeincreases.Thelineswillnotintersect.Forproblems21–23,refertoFigure2-18.21.TimeUsetheposition-timegraphoftheSectionReviewhockeypucktodeterminewhenitwas10.0mbeyondtheorigin.2.3Position-TimeGraphs0.5spages38–42page4222.DistanceUsetheposition-timegraphof19.Position-TimeGraphFromtheparticlethehockeypucktodeterminehowfaritmodelinFigure2-17ofababycrawlingmovedbetween0.0sand5.0s.acrossakitchenfloor,plotaposition-time100mgraphtorepresenthismotion.Thetimeintervalbetweensuccessivedotsis1s.23.TimeIntervalUsetheposition-timegraphforthehockeypucktodeterminehowmuchtimeittookforthepucktogofrom40m020406080100120140160beyondtheoriginto80mbeyondtheorigin.Position(cm)2.0s■Figure2-1716024.CriticalThinkingLookattheparticle140modelandposition-timegraphshownin120100Figure2-19.Dotheydescribethesame8060motion?Howdoyouknow?DonotPosition(m)40confusethepositioncoordinatesysteminCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.200theparticlemodelwiththehorizontalaxis12345678intheposition-timegraph.Thetimeinter-Time(s)valsintheparticlemodelare2s.20.MotionDiagramCreateaparticlemodelfromtheposition-timegraphofahockey010puckglidingacrossafrozenpondinPosition(m)Figure2-18.12140120100880604Position(m)Position(m)402000.01.02.03.04.05.06.07.012345Time(s)Time(s)■Figure2-19■Figure2-1818SolutionsManualPhysics:PrinciplesandProblems
22Chapter2continuedNo,theydon’tdescribethesame26.Describe,inwords,themotionofthecruisemotion.Althoughbothobjectsaretrav-shipinthepreviousproblem.elinginthepositivedirection,oneisTheshipismovingtothenorthatamovingmorequicklythantheother.speedof0.33m/s.Studentscanciteanumberofdifferentspecificexamplesfromthegraphand27.ThegraphinFigure2-23representstheparticlemodeltobackthisup.motionofabicycle.Determinethebicycle’saveragespeedandaveragevelocity,anddescribeitsmotioninwords.PracticeProblems202.4HowFast?15pages43–4710page4525.ThegraphinFigure2-22describesthe5Position(km)motionofacruiseshipduringitsvoyagethroughcalmwaters.Thepositive051015202530d-directionisdefinedtobesouth.Time(min)■Figure2-23Time(s)Becausethebicycleismovinginthe12340positivedirection,theaveragespeedandaveragevelocityarethesame.Usingthepoints(0.0min,0.0km)and�1(15.0min,10.0km),Position(m)�d�2v�����td�d■Figure2-2221���t2�t1a.Whatistheship’saveragespeed?10.0km�0.0kmUsingthepoints(0.0s,0.0m)and����15.0min�0.0min(3.0s,�1.0m)�0.67km/min�dv����v��0.67km/mininthepositive�tdirectiond�d21���Thebicycleismovinginthepositivet2�t1directionataspeedof0.67km/min.�1.0m�0.0m���3.0s�0.0s��0.33m/s�0.33m/sb.Whatisitsaveragevelocity?Theaveragevelocityistheslopeoftheline,includingthesign,soitisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.33m/sor0.33m/snorth.Physics:PrinciplesandProblemsSolutionsManual19
23Chapter2continued28.WhenMarilyntakesherpetdogforawalk,SlopeA��2thedogwalksataveryconsistentpaceof3Slope��B�20.55m/s.Drawamotiondiagramandposi-Slopetion-timegraphtorepresentMarilyn’sdogC��1Slopewalkingthe19.8-mdistancefrominfrontD�1ofherhousetothenearestfirehydrant.30.AverageVelocityRankthegraphsaccord-MotionDiagramingtoaveragevelocity,fromgreatestaveraget0�0st6�36svelocitytoleastaveragevelocity.Specificallyindicateanyties.B,D,C,A0.0m19.8mHouseHydrantSlopeA��23Slope��Position-TimeGraphB�220.0SlopeC��115.0SlopeD�110.031.InitialPositionRankthegraphsaccordinghouse(m)5.0totheobject’sinitialposition,frommostPositionfrompositivepositiontomostnegativeposition.061218243036Specificallyindicateanyties.WouldyourTime(s)rankingbedifferentifyouhadbeenaskedtodotherankingaccordingtoinitialdistancefromtheorigin?SectionReviewA,C,B,D.Yes,therankingfromgreatesttoleastdistancewouldbeA,C,D,B.2.4HowFast?pages43–4732.AverageSpeedandAverageVelocitypage47ExplainhowaveragespeedandaverageCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Forproblems29–31,refertoFigure2-25.velocityarerelatedtoeachother.29.AverageSpeedRanktheposition-timeAveragespeedistheabsolutevalueofgraphsaccordingtotheaveragespeedofthetheaveragevelocity.Speedisonlyaobject,fromgreatestaveragespeedtoleastmagnitude,whilevelocityisamagni-averagespeed.Specificallyindicateanyties.tudeandadirection.BDAPosition(m)CTime(s)■Figure2-25Forspeedusetheabsolutevalue,there-foreA,B,C�D20SolutionsManualPhysics:PrinciplesandProblems
24Chapter2continued33.CriticalThinkingInsolvingaphysics37.Thefollowingquantitiesdescribelocationproblem,whyisitimportanttocreateoritschange:position,distance,anddis-pictorialandphysicalmodelsbeforetryingplacement.Brieflydescribethedifferencestosolveanequation?amongthem.(2.2)Answerswillvary,butherearesomeofPositionanddisplacementaredifferenttheimportantpoints.Drawingthemod-fromdistancebecausepositionanddis-elsbeforewritingdowntheequationplacementbothcontaininformationhelpsyoutogettheproblemsituationaboutthedirectioninwhichanobjectorganizedinyourhead.It’sdifficulttohasmoved,whiledistancedoesnot.writedowntheproperequationifyouDistanceanddisplacementaredifferentdon’thaveaclearpictureofhowthingsfrompositionbecausetheydescribearesituatedand/ormoving.Also,youhowanobject’slocationhaschangedchoosethecoordinatesysteminthisduringatimeinterval,wherepositionstep,andthisisessentialinmakingtellsexactlywhereanobjectislocatedsureyouusethepropersignsontheataprecisetime.quantitiesyouwillsubstituteintotheequationlater.38.Howcanyouuseaclocktofindatimeinterval?(2.2)ReadtheclockatthebeginningandChapterAssessmentendoftheintervalandsubtractthebeginningtimefromtheendingtime.ConceptMappingpage5239.In-lineSkatingHowcanyouusethe34.Completetheconceptmapbelowusingtheposition-timegraphsfortwoin-lineskatersfollowingterms:words,equivalentrepresenta-todetermineifandwhenonein-lineskatertions,position-timegraph.willpasstheotherone?(2.3)Drawthetwographsonthesamesetofaxes.Oneinlineskaterwillpassthewordsotherifthelinesrepresentingeachoftheirmotionsintersect.Thepositioncoordinateofthepointwherethelinesequivalentdataposition-timemotionintersectisthepositionwheretherepresentationstablegraphdiagrampassingoccurs.40.WalkingVersusRunningAwalkerandaMasteringConceptsrunnerleaveyourfrontdooratthesamepage52time.Theymoveinthesamedirectionat35.Whatisthepurposeofdrawingamotiondifferentconstantvelocities.Describethediagram?(2.1)position-timegraphsofeach.(2.4)AmotiondiagramgivesyouapictureBotharestraightlinesthatstartattheofmotionthathelpsyouvisualizesameposition,buttheslopeofthedisplacementandvelocity.runner’slineissteeper.36.Underwhatcircumstancesisitlegitimateto41.Whatdoestheslopeofaposition-timeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.treatanobjectasapointparticle?(2.1)graphmeasure?(2.4)Anobjectcanbetreatedasapointvelocityparticleifinternalmotionsarenotimportantandiftheobjectissmallincomparisontothedistanceitmoves.Physics:PrinciplesandProblemsSolutionsManual21
25Chapter2continued42.Ifyouknowthepositionsofamoving46.Figure2-26isagraphoftwopeoplerunning.objectattwopointsalongitspath,andyoualsoknowthetimeittookfortheobjecttoBregetfromonepointtotheother,canyounnuRdeterminetheparticle’sinstantaneousRunnerAvelocity?Itsaveragevelocity?Explain.(2.4)ItispossibletocalculatetheaveragePosition(m)velocityfromtheinformationgiven,butitisnotpossibletofindtheinstanta-neousvelocity.Time(s)■Figure2-26ApplyingConceptsa.DescribethepositionofrunnerApage52relativetorunnerBatthey-intercept.43.TestthefollowingcombinationsandRunnerAhasaheadstartbyexplainwhyeachdoesnothavetheproper-fourunits.tiesneededtodescribetheconceptofveloc-b.Whichrunnerisfaster?ity:�d��t,�d��t,�d��t,�t/�d.RunnerBisfaster,asshownby�d��tincreaseswheneithertermthesteeperslope.increases.Thesignof�d��tdependsc.WhatoccursatpointPandbeyond?upontherelativesizesof�dand�t.�d��tincreaseswheneitherincreas-RunnerBpassesrunnerAatpointes.�t/�ddecreaseswithincreasingP.displacementandincreaseswithincreasingtimeinterval,whichisback-47.Theposition-timegraphinFigure2-27wardsfromvelocity.showsthemotionoffourcowswalkingfromthepasturebacktothebarn.Rankthe44.FootballWhencanafootballbeconsid-cowsaccordingtotheiraveragevelocity,eredapointparticle?fromslowesttofastest.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.AfootballcanbetreatedasapointparticleifitsrotationsarenotimportanteandifitissmallincomparisontotheislBessieEdistanceitmoves—fordistancesofdalin1yardormore.MooylloD45.WhencanafootballplayerbetreatedasaPosition(m)pointparticle?AfootballplayercanbetreatedasapointparticleifhisorherinternalTime(s)motionsarenotimportantandifheor■Figure2-27sheissmallincomparisontothedis-Moolinda,Dolly,Bessie,Elsietanceheorshemoves—fordistancesofseveralyardsormore.22SolutionsManualPhysics:PrinciplesandProblems
26Chapter2continued48.Figure2-28isaposition-timegraphforarabbitrunningawayfromadog.321Position(m)0123Time(s)■Figure2-28a.Describehowthisgraphwouldbedifferentiftherabbitrantwiceasfast.Theonlydifferenceisthattheslopeofthegraphwouldbetwiceassteep.b.Describehowthisgraphwouldbedif-ferentiftherabbitranintheoppositedirection.Themagnitudeoftheslopewouldbethesame,butitwouldbenegative.MasteringProblems2.4HowFast?page53Level149.Abiketravelsataconstantspeedof4.0m/sfor5.0s.Howfardoesitgo?d�vt�(4.0m/s)(5s)�20m50.AstronomyLightfromtheSunreachesEarthin8.3min.Thespeedoflightis3.00�108m/s.HowfarisEarthfromtheSun?d�vt8m/s)(8.3min)60s�(3.00�10����1min�1.5�1011mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual23
27Chapter2continuedLevel2pages53–5451.Acarismovingdownastreetat55km/h.ALevel1childsuddenlyrunsintothestreet.Ifit54.CyclingAcyclistmaintainsaconstanttakesthedriver0.75storeactandapplyvelocityof�5.0m/s.Attimet�0.0s,thethebrakes,howmanymeterswillthecarcyclistis�250mfrompointA.havemovedbeforeitbeginstoslowdown?a.Plotaposition-timegraphofthed�vtcyclist’slocationfrompointAat10.0-s1000m1h�(55km/h)(0.75s)��������intervalsfor60.0s.1km3600s�11m55050052.Norajogsseveraltimesaweekandalwayskeepstrackofhowmuchtimesheruns450eachtimeshegoesout.Onedaysheforgets400totakeherstopwatchwithherandwonders350ifthere’sawayshecanstillhavesomeideaPosition(m)300ofhertime.Asshepassesaparticularbank,sheremembersthatitis4.3kmfromher250house.Sheknowsfromherprevious200trainingthatshehasaconsistentpaceof0.010.020.030.040.050.060.04.0m/s.HowlonghasNorabeenjoggingTime(s)whenshereachesthebank?b.Whatisthecyclist’spositionfrompointd�vtAat60.0s?1000m550m(4.3km)����d1kmt������c.Whatisthedisplacementfromthev4.0m/sstartingpositionat60.0s?�1075s550m�250m�3.0�102m1min�(1075s)����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.60s55.Figure2-29isaparticlemodelfora�18minchickencasuallywalkingacrosstheroad.Timeintervalsareevery0.1s.Drawthecorrespondingposition-timegraphandLevel3equationtodescribethechicken’smotion.53.DrivingYouandafriendeachdrive50.0km.Youtravelat90.0km/h;yourThissideTheothersidefriendtravelsat95.0km/h.HowlongwillyourfriendhavetowaitforyouattheendTimeintervalsare0.1s.ofthetrip?■Figure2-29d�vtd50.0kmdt�����1�v90.0km/hTheotherside�0.556hd50.0kmt�����2�v95.0km/h�0.526h60mint1�t2�(0.556h�0.526h)��1�h�Thissidet�1.8min01.9sMixedReview56.Figure2-30showsposition-timegraphsfor24SolutionsManualPhysics:PrinciplesandProblems
28Chapter2continuedJosziandHeikepaddlingcanoesinalocal250river.CarB2001817016CarAJoszi15014120Heike1210010Position(km)508Position(km)601.01.63.041.42.02Time(h)00.51.01.52.02.5Time(h)b.Bothcarspassedagasstation120km■Figure2-30fromtheschool.Whendideachcarpassthegasstation?Calculatethetimesa.Atwhattime(s)areJosziandHeikeinandshowthemonyourgraph.thesameplace?1.0hd120kmt������1.6hA��75km/hAb.HowmuchtimedoesJoszispendontheriverbeforehepassesHeike?d120kmt������1.4hB��85km/h45minBc.Whereontheriverdoesitappearthat58.Drawaposition-timegraphfortwocarstheremightbeaswiftcurrent?travelingtothebeach,whichis50kmfromfrom6.0to9.0kmfromtheoriginschool.Atnoon,CarAleavesastorethatis10kmclosertothebeachthantheschoolisandmovesat40km/h.CarBstartsfromLevel2schoolat12:30P.M.andmovesat100km/h.57.DrivingBothcarAandcarBleaveschoolWhendoeseachcargettothebeach?whenastopwatchreadszero.CarAtravelsataconstant75km/h,andcarBtravelsata50constant85km/h.40a.Drawaposition-timegraphshowingCarA30themotionofbothcars.Howfarare20CarBthetwocarsfromschoolwhenthestop-watchreads2.0h?Calculatethedis-Position(m)10tancesandshowthemonyourgraph.0Noon12101220123012401250100PMdA�vAt�(75km/h)(2.0h)Time�150kmBothcarsarriveatthebeachat1:00P.M.dB�vBt�(85km/h)(2.0h)Level3Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�170km59.Twocarstravelalongastraightroad.Whenastopwatchreadst�0.00h,carAisatdA�48.0kmmovingataconstant36.0km/h.Later,whenthewatchreadst�0.50h,carBisatdB�0.00kmmovingPhysics:PrinciplesandProblemsSolutionsManual25
29Chapter2continuedat48.0km/h.Answerthefollowingques-60.Figure2-31showstheposition-timegraphtions,first,graphicallybycreatingaposi-depictingJim’smovementupanddownthetion-timegraph,andsecond,algebraicallyaisleatastore.Theoriginisatoneendofbywritingequationsforthepositionstheaisle.dAanddBasafunctionofthestopwatch14.0time,t.a.WhatwillthewatchreadwhencarB12.0passescarA?10.0300.08.06.0200.0Position(m)4.0150.0CarA2.0150.0Position(km)CarB0.0010.020.030.040.050.060.0100.0Time(s)50.0■Figure2-31a.WriteastorydescribingJim’smovements�1.000.001.002.003.004.005.006.007.00atthestorethatwouldcorrespondtotheTime(h)motionrepresentedbythegraph.Answerswillvary.Carspasswhenthedistancesareequal,db.WhendoesJimhaveapositionof6.0m?A�dBdfrom8.0to18.0s,53.0to56.0s,andA�48.0km�(36.0km/h)tat43.0sanddB�0�(48.0km/h)(t�0.50h)c.Howmuchtimepassesbetweenwhenso48.0km�(36.0km/h)tJimenterstheaisleandwhenhegetstoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(48.0km/h)(t�0.50h)apositionof12.0m?WhatisJim’saver-(48.0km)�(36.0km/h)tagevelocitybetween37.0sand46.0s?�(48.0km/h)t�24kmt�33.0s72km�(12.0km/h)tUsingthepoints(37.0s,12.0m)andt�6.0h(46.0s,3.00m)b.AtwhatpositionwillcarBpasscarA?df�di3.00m�12.0mdv������A�48.0km�(36.0km/h)(6.0h)tf�ti46.0s�37.0s�2.6�102km��1.00m/sc.Whenthecarspass,howlongwillithavebeensincecarAwasatthereferencepoint?d�vtd�48.0kmsot��������1.33hv36.0km/hCarAhasstarted1.33hbeforetheclockstarted.t�6.0h�1.33h�7.3h26SolutionsManualPhysics:PrinciplesandProblems
30Chapter2continuedThinkingCriticallyExplanation:Assumeyouwanttotravel90kmin1h.page54Ifyoucoverthefirsthalfofthedistance61.ApplyCalculatorsMembersofaphysicsat48km/h,thenyou’vegone45kminclassstood25mapartandusedstopwatch-destomeasurethetimewhichacartraveling0.9375h(becauset���).Thismeansvonthehighwaypassedeachperson.Theiryouhaveused93.75%ofyourtimefordataareshowninTable2-3.thefirsthalfofthedistanceleaving6.25%ofthetimetogotheremainingTable2-345km.Positionv.Time45kmv���Time(s)Position(m)0.0625h0.00.0�720km/h1.325.063.DesignanExperimentEverytimeapar-2.750.0ticularredmotorcycleisdrivenpastyour3.675.0friend’shome,hisfatherbecomesangrybecausehethinksthemotorcycleisgoing5.1100.0toofastfortheposted25mph(40km/h)5.9125.0speedlimit.Describeasimpleexperiment7.0150.0youcoulddotodeterminewhetherornotthemotorcycleisspeedingthenexttimeit8.6175.0isdrivenpastyourfriend’shouse.10.3200.0Thereareactuallyseveralgoodpossibil-Useagraphingcalculatortofitalinetoaitiesforanswersonthisone.Twothatposition-timegraphofthedataandtoplotshouldbeamongthemostpopulararethisline.Besuretosetthedisplayrangeofbrieflydescribedhere.1)Getseveralthegraphsothatallthedatafitonit.Findpeopletogetherandgiveeveryoneatheslopeoftheline.Whatwasthespeedofwatch.Synchronizethewatchesandthecar?standalongthestreetseparatedbyaconsistentdistance,maybe10morso.200.0Whenthemotorcyclepasses,haveeach150.0personrecordthetime(atleasttoan100.0accuracyofseconds)thatthemotorcy-clecrossedinfrontofthem.Plotaposi-50.0Position(m)tiontimegraph,andcomputetheslope0.02.04.06.08.010.012.0ofthebest-fitline.Iftheslopeisgreaterthan25mph,themotorcycleisspeed-Time(s)ing.2)Getsomeonewithadriver’sTheslopeofthelineandthespeedoflicensetodriveacaralongthestreetatthecarare19.7m/s.25mphinthesamedirectionasyouexpectthemotorcycletogo.Ifthe62.ApplyConceptsYouplanacartripformotorcyclegetsclosertothecar(ifthewhichyouwanttoaverage90km/h.Youdistancebetweenthemdecreases),theCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.coverthefirsthalfofthedistanceatanmotorcycleisspeeding.Ifthedistanceaveragespeedofonly48km/h.Whatmustbetweenthemstaysthesame,theyouraveragespeedbeinthesecondhalfofmotorcycleisdrivingatthespeedlimit.thetriptomeetyourgoal?Isthisreason-Ifthedistanceincreases,themotorcycleable?Notethatthevelocitiesarebasedonisdrivinglessthanthespeedlimit.halfthedistance,nothalfthetime.720km/h;No64.InterpretGraphsIsitpossibleforanPhysics:PrinciplesandProblemsSolutionsManual27
31Chapter2continuedobject’sposition-timegraphtobeahori-CumulativeReviewzontalline?Averticalline?Ifyouanswerpage54yestoeithersituation,describetheassociat-67.Converteachofthefollowingtimemea-edmotioninwords.surementstoitsequivalentinseconds.Itispossibletohaveahorizontalline(Chapter1)asaposition-timegraph;thiswoulda.58nsindicatethattheobject’spositionisnot5.8�10�8schanging,orinotherwords,thatitisnotmoving.Itisnotpossibletohaveab.0.046Gsposition-timegraphthatisavertical4.6�107sline,becausethiswouldmeanthec.9270msobjectismovingataninfinitespeed.9.27sWritinginPhysicsd.12.3kspage541.23�104s65.Physicistshavedeterminedthatthespeedoflightis3.00�108m/s.Howdidtheyarrive68.Statethenumberofsignificantdigitsinthefollowingmeasurements.(Chapter1)atthisnumber?Readaboutsomeoftheseriesofexperimentsthatweredonetoa.3218kgdeterminelight’sspeed.Describehowthe4experimentaltechniquesimprovedtomakeb.60.080kgtheresultsoftheexperimentsmoreaccurate.5Answerswillvary.Galileoattemptedtoc.801kgdeterminethespeedoflightbutwasunsuccessful.DanishastronomerOlaus3Roemersuccessfullymeasuredthed.0.000534kgspeedoflightin1676byobservingthe3eclipsesofthemoonsofJupiter.HisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.estimatewas140,000miles/s(225,30869.Usingacalculator,Chrisobtainedthefol-km/s).Manyotherssincehavetriedtolowingresults.Rewritetheanswertoeachmeasureitmoreaccuratelyusingrotat-operationusingthecorrectnumberofsig-ingtoothedwheels,rotatingmirrorsandnificantdigits.(Chapter1)theKerrcellshutter.a.5.32mm�2.1mm�7.4200000mm7.4mm66.Somespeciesofanimalshavegoodendurance,whileothershavetheabilitytob.13.597m�3.65m�49.62905m2moveveryquickly,butforonlyashort49.6m2amountoftime.Usereferencesourcestoc.83.2kg�12.804kg�70.3960000kgfindtwoexamplesofeachqualityand70.4kgdescribehowitishelpfultothatanimal.Answerswillvary.Examplesofanimalswithhighendurancetooutlastpreda-torsorpreyincludemules,bears,andcoyotes.Animalswiththespeedtoquicklyescapepredatorsorcapturepreyincludecheetahs,antelopesanddeer.28SolutionsManualPhysics:PrinciplesandProblems
32CHAPTER3AcceleratedMotion3.Refertothev-tgraphofthetoytrainPracticeProblemsinFigure3-6toanswerthefollowing3.1Accelerationquestions.pages57–6412.0page6110.01.Adogrunsintoaroomandseesacatatthe8.0otherendoftheroom.Thedoginstantly6.0stopsrunningbutslidesalongthewood4.0flooruntilhestops,byslowingdownwithaVelocity(m/s)2.0constantacceleration.Sketchamotiondia-0.0gramforthissituation,andusethevelocity10.020.030.040.0vectorstofindtheaccelerationvector.Time(s)■Figure3-6123Timea.Whenisthetrain’sspeedconstant?intervalv1v2v3Velocity5.0to15.0sb.Duringwhichtimeintervalisthetrain’sPositionStartStopaccelerationpositive?v2�v10.0to5.0sac.Whenisthetrain’saccelerationmostnegative?2.Figure3-5isav-tgraphforStevenashe15.0to20.0swalksalongthemidwayatthestatefair.Sketchthecorrespondingmotiondiagram,4.RefertoFigure3-6tofindtheaveragecompletewithvelocityvectors.accelerationofthetrainduringthefollow-ingtimeintervals.a.0.0sto5.0sva���2�v1t2�t110.0m/s�0.0m/s����5.0s�0.0sVelocity(m/s)�2.0m/s2011234567890b.15.0sto20.0sTime(s)v■Figure3-5a���2�v1t2�t14.0m/s�10.0m/s����Time(s)0123456819020.0s�15.0sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.7��1.2m/s2c.0.0sto40.0sva���2�v1t2�t1Physics:PrinciplesandProblemsSolutionsManual29
33Chapter3continued0.0m/s�0.0m/sa.Whatistheaverageaccelerationofthe����40.0s�0.0sbuswhilebraking?�0.0m/s2�va�����t5.Plotav-tgraphrepresentingthefollowing0.0m/s�25m/s2������8.3m/smotion.Anelevatorstartsatrestfromthe3.0sgroundfloorofathree-storyshoppingb.Ifthebustooktwiceaslongtostop,mall.Itacceleratesupwardfor2.0satahowwouldtheaccelerationcomparerateof0.5m/s2,continuesupatacon-withwhatyoufoundinparta?stantvelocityof1.0m/sfor12.0s,and2)halfasgreat(�4.2m/sthenexperiencesaconstantdownwardaccelerationof0.25m/s2for4.0sasit10.Rohithhasbeenjoggingtothebusstopforreachesthethirdfloor.2.0minat3.5m/swhenhelooksathiswatchandseesthathehasplentyoftime1.0beforethebusarrives.Overthenext10.0s,heslowshispacetoaleisurely0.75m/s.Whatwashisaverageaccelerationduringthis10.0s?Velocity(m/s)�va�����t0.05.010.015.020.00.75m/s�3.5m/s����Time(s)10.0s��0.28m/s2page6411.Iftherateofcontinentaldriftwereto6.Aracecar’svelocityincreasesfrom4.0m/sabruptlyslowfrom1.0cm/yrto0.5cm/yrto36m/sovera4.0-stimeinterval.Whatisoverthetimeintervalofayear,whatwoulditsaverageacceleration?betheaverageacceleration?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a�����v�����36m/s�4.0m/s8.0m/s2�v0.5cm/yr�1.0cm/yr�t4.0sa�����t����1.0yr��0.5cm/yr27.Theracecarinthepreviousproblemslowsfrom36m/sto15m/sover3.0s.Whatisitsaverageacceleration?SectionReview�v15m/s�36m/s2a���������7.0m/s�t3.0s3.1Accelerationpages57–648.Acariscoastingbackwardsdownhillatapage64speedof3.0m/swhenthedrivergetsthe12.Velocity-TimeGraphWhatinformationenginestarted.After2.5s,thecarismovingcanyouobtainfromavelocity-timegraph?uphillat4.5m/s.Ifuphillischosenasthepositivedirection,whatisthecar’saverageThevelocityatanytime,thetimeatacceleration?whichtheobjecthadaparticularvelocity,thesignofthevelocity,andthe�v4.5m/s�(�3.0m/s)2a���������3.0m/sdisplacement.�t2.5s13.Position-TimeandVelocity-TimeGraphs9.Abusismovingat25m/swhenthedriverTwojoggersrunataconstantvelocityofstepsonthebrakesandbringsthebustoa7.5m/stowardtheeast.Attimet�0,onestopin3.0s.30SolutionsManualPhysics:PrinciplesandProblems
34Chapter3continuedis15meastoftheoriginandtheotheris16.AverageVelocityandAverageAcceleration15mwest.Acanoeistpaddlesupstreamat2m/sanda.Whatwouldbethedifference(s)inthethenturnsaroundandfloatsdownstreamatposition-timegraphsoftheirmotion?4m/s.Theturnaroundtimeis8s.Bothlineswouldhavethesamea.Whatistheaveragevelocityofthecanoe?slope,buttheywouldrisefromtheChooseacoordinatesystemwithd-axisatdifferentpoints,�15m,thepositivedirectionupstream.and�15m.vv���i�vfb.Whatwouldbethedifference(s)intheir2velocity-timegraphs?2m/s�(�4m/s)����Theirvelocity-timegraphswouldbe2identical.��1m/sb.Whatistheaverageaccelerationofthe14.VelocityExplainhowyouwoulduseacanoe?velocity-timegraphtofindthetimeat�vwhichanobjecthadaspecifiedvelocity.a�����tDraworimagineahorizontallineatthev�v�f�ispecifiedvelocity.Findthepointwhere��tthegraphintersectsthisline.Dropa(�4m/s)�(2m/s)linestraightdowntothet-axis.This����8swouldbetherequiredtime.�0.8m/s215.Velocity-TimeGraphSketchavelocity-time17.CriticalThinkingApoliceofficerclockedgraphforacarthatgoeseastat25m/sforadrivergoing32km/hoverthespeedlimit100s,thenwestat25m/sforanother100s.justasthedriverpassedaslowercar.Both25driverswereissuedspeedingtickets.Thejudgeagreedwiththeofficerthatbothwereguilty.ThejudgementwasissuedbasedonTime(s)theassumptionthatthecarsmusthave100200beengoingthesamespeedbecausetheyVelocity(m/s)wereobservednexttoeachother.Arethe�25judgeandthepoliceofficercorrect?Explainwithasketch,amotiondiagram,andaposition-timegraph.No,theyhadthesameposition,notvelocity.Tohavethesamevelocity,theywouldhavehadtohavethesamerela-tivepositionforalengthoftime.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual31
35Chapter3continuedSketchPosition-TimeGraphMotiondiagramPassing4positiont0t1t2t3t43Fastercar2Position10Slowercart0t1t2t3t4t1t2t3t4TimePracticeProblems3.2MotionwithConstantAccelerationpages65–71page6518.Agolfballrollsupahilltowardaminiature-golfhole.Assumethatthedirectiontowardtheholeispositive.a.Ifthegolfballstartswithaspeedof2.0m/sandslowsataconstantrateof0.50m/s2,whatisitsvelocityafter2.0s?vf�vi�at�2.0m/s�(�0.50m/s2)(2.0s)�1.0m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Whatisthegolfball’svelocityiftheconstantaccelerationcontinuesfor6.0s?vf�vi�at�2.0m/s�(�0.50m/s2)(6.0s)��1.0m/sc.Describethemotionofthegolfballinwordsandwithamotiondiagram.Theball’svelocitysimplydecreasedinthefirstcase.Inthesecondcase,theballslowedtoastopandthenbeganrollingbackdownthehill.Timeinterval1234Velocity�dPositionVelocityTimeinterval6519.Abusthatistravelingat30.0km/hspeedsupataconstantrateof3.5m/s2.Whatvelocitydoesitreach6.8slater?vf�vi�at2)(6.8s)1km3600s�30.0km/h�(3.5m/s��������1000m1h�120km/h32SolutionsManualPhysics:PrinciplesandProblems
36Chapter3continued20.Ifacaracceleratesfromrestataconstantb.2.0s5.5m/s2,howlongwillittakeforthecartoAt2.0s,v�78m/sreachavelocityof28m/s?c.2.5svf�vi�atAt2.5s,v�80m/svvsot�f��i�a23.Usedimensionalanalysistoconvertan28m/s�0.0m/sairplane’sspeedof75m/stokm/h.����5.5m/s23600s1km2km/h(75m/s)���������2.7�10�5.1s1h1000m21.Acarslowsfrom22m/sto3.0m/sata24.Aposition-timegraphforaponyrunningconstantrateof2.1m/s2.HowmanyinafieldisshowninFigure3-12.Drawsecondsarerequiredbeforethecaristhecorrespondingvelocity-timegraphusingtravelingat3.0m/s?thesametimescale.vf�vi�at�yvvsot�f��i�a3.0m/s�22m/s�����2.1m/s2�xTime(s)�9.0sDisplacement(m)■Figure3-12page67�yPosition-timegraph22.UseFigure3-11todeterminethevelocityofanairplanethatisspeedingupateachofSpeedsthefollowingtimes.up82Time(s)80Velocity(m/s)�xDisplacement(m)Stopsand78SpeedsSlowsturnsaroundupdown7674Velocity(m/s)25.Acarisdrivenataconstantvelocityof7225m/sfor10.0min.Thecarrunsoutofgas70andthedriverwalksinthesamedirection0.01.02.03.0at1.5m/sfor20.0mintothenearestgasTime(s)station.Thedrivertakes2.0mintofilla■Figure3-11gasolinecan,thenwalksbacktothecaratGraphBrepresentsconstantspeed.So1.2m/sandeventuallydriveshomeatgraphAshouldbeusedforthefollow-25m/sinthedirectionoppositethatofingcalculations.theoriginaltrip.a.1.0sa.Drawav-tgraphusingsecondsasyourCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.timeunit.Calculatethedistancethedri-At1.0s,v�74m/sverwalkedtothegasstationtofindthetimeittookhimtowalkbacktothecar.Physics:PrinciplesandProblemsSolutionsManual33
37Chapter3continuedv25f�vi�at20vf�vi0.0m/s�1.75m/st��������28.8s15a�0.20m/s1027.Aracecartravelsonaracetrackat44m/s5andslowsataconstantratetoavelocity0Time(s)of22m/sover11s.Howfardoesitmove�5500duringthistime?Velocity(m/s)1000150020002500300035004000�10�15�v(vf�vi)v�������22�20�25�d�v��t(vv�f��i)�tdistancethedriverwalkedtothe�2gasstation:(22m/s�44m/s)(11s)����d�vt2�(1.5m/s)(20.0min)(60s/min)��1.2�102m�1800m28.Acaracceleratesataconstantratefrom�1.8km15m/sto25m/swhileittravelsadistancetimetowalkbacktothecar:of125m.Howlongdoesittaketoachieved1800mthisspeed?t�������1500s�25minv1.2m/s�v(vf�vi)b.Drawaposition-timegraphforthev�������22situationusingtheareasunderthe�d�v��tvelocity-timegraph.(vv�f��i)�t20,000�2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2�d�t��15,000(vf�vi)(2)(125m)���10,00025m/s�15m/s�25sPosition(m)500029.Abikeriderpedalswithconstantaccelera-tiontoreachavelocityof7.5m/soveratimeof4.5s.Duringtheperiodofaccelera-010002000300040005000tion,thebike’sdisplacementis19m.WhatTime(s)wastheinitialvelocityofthebike?page69�v(vf�vi)26.Askateboarderismovingataconstantv���2���2�velocityof1.75m/swhenshestartsupan(vv�d�v��t�f��i)�tinclinethatcauseshertoslowdownwitha�2constantaccelerationof�0.20m/s2.How2�dmuchtimepassesfromwhenshebeginstosovi����t�vfslowdownuntilshebeginstomovebackdowntheincline?��(2)(19�m)4.5s�7.5m/s�0.94m/s34SolutionsManualPhysics:PrinciplesandProblems
38Chapter3continuedpage7130.Amanrunsatavelocityof4.5m/sfor15.0min.Whengoingupanincreasinglysteephill,heslowsdownataconstantrateof0.05m/s2for90.0sandcomestoastop.Howfardidherun?1d�v��(v1t1�22f�v2i)t21�(4.5m/s)(15.0min)(60s/min)���(0.0m/s�4.5m/s)(90.0s)2�4.3�103m31.Sekaziislearningtorideabikewithouttrainingwheels.Hisfatherpusheshimwithaconstantaccelerationof0.50m/s2for6.0s,andthenSekazicontinuesat3.0m/sforanother6.0sbeforefalling.WhatisSekazi’sdisplacement?Solvethisproblembyconstructingavelocity-timegraphforSekazi’smotionandcomput-ingtheareaunderneaththegraphedline.3.012Velocity(m/s)6.012.0Time(s)Part1:Constantacceleration:1d��(3.0m/s)(6.0s)1�2�9.0mPart2:Constantvelocity:d2�(3.0m/s)(12.0s�6.0s)�18mThusd�d1�d2�9.0m�18m�27m32.Youstartyourbicyclerideatthetopofahill.Youcoastdownthehillatacon-stantaccelerationof2.00m/s2.Whenyougettothebottomofthehill,youaremovingat18.0m/s,andyoupedaltomaintainthatspeed.Ifyoucontinueatthisspeedfor1.00min,howfarwillyouhavegonefromthetimeyouleftthehilltop?Part1:Constantacceleration:v2�v2�2a(dfif�di)anddi�0.00mv2�v2sod�f�if�2asincevi�0.00m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2vd�f�f�2a(18.0m/s)2���(2)(2.00m/s2)�81.0mPhysics:PrinciplesandProblemsSolutionsManual35
39Chapter3continuedPart2:Constantvelocity:d3m2�vt�(18.0m/s)(60.0s)�1.08�10Thusd�d1�d2�81.0m�1.08�103m�1.16�103m33.Suneeistrainingforanupcoming5.0-kmrace.Shestartsouthertrainingrunbymovingataconstantpaceof4.3m/sfor19min.Thensheacceleratesataconstantrateuntilshecrossesthefinishline,19.4slater.Whatisheraccelerationduringthelastportionofthetrainingrun?Part1:Constantvelocity:d�vt�(4.3m/s)(19min)(60s/min)�4902mPart2:Constantacceleration:12d��atf�di�vit�22(df�di�vit)(2)(5.0�103m�4902m�(4.3m/s)(19.4s))a����������t2(19.4s)2�0.077m/s2SectionReview3.2MotionwithConstantAccelerationCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pages65–71page7134.AccelerationAwomandrivingataspeedof23m/sseesadeerontheroadaheadandappliesthebrakeswhensheis210mfromthedeer.Ifthedeerdoesnotmoveandthecarstopsrightbeforeithitsthedeer,whatistheaccelerationprovidedbythecar’sbrakes?v2�v2�2a(dfif�di)v2�v2a�f�i�2(d�dfi)0.0m/s�(23m/s)2����(2)(210m)��1.3m/s235.DisplacementIfyouweregiveninitialandfinalvelocitiesandtheconstantaccelerationofanobject,andyouwereaskedtofindthedisplacement,whatequationwouldyouuse?v2�v2�2adfif36SolutionsManualPhysics:PrinciplesandProblems
40Chapter3continued36.DistanceAnin-lineskaterfirstacceleratesfrom0.0m/sto5.0m/sin4.5s,thencontinuesatthisconstantspeedforanother4.5s.Whatisthetotaldistancetrav-eledbythein-lineskater?Acceleratingvvd�i��f(tf�v�tf�2f)0.0m/s�5.0m/s������(4.5s)2�11.25mConstantspeeddf�vftf�(5.0m/s)(4.5s)�22.5mtotaldistance�11.25m�22.5m�34m37.FinalVelocityAplanetravelsadistanceof5.0�102mwhilebeingaccelerateduniformlyfromrestattherateof5.0m/s2.Whatfinalvelocitydoesitattain?v2�v2�2a(dfff�di)anddi�0,sov2�v2�2adfffvf��(0.0m��/s)2��2(5.0m/s�2)(�5.0�1�02m)�71m/s38.FinalVelocityAnairplaneaccelerateduniformlyfromrestattherateof5.0m/s2for14s.Whatfinalvelocitydiditattain?vf�vi�atf�0�(5.0m/s2)(14s)�7.0�101m/s39.DistanceAnairplanestartsfromrestandacceleratesataconstant3.00m/s2for30.0sbeforeleavingtheground.a.Howfardiditmove?12d��atf�vitf�2f�(0.0m/s)(30.0s)2���1��2)(30.0s)2(3.00m/s2�1.35�103mb.Howfastwastheairplanegoingwhenittookoff?vf�vi�atfCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.0m/s�(3.00m/s2)(30.0s)�90.0m/sPhysics:PrinciplesandProblemsSolutionsManual37
41Chapter3continued40.GraphsAsprinterwalksuptothestartingblocksataconstantspeedandpositionsherselfforthestartoftherace.Shewaitsuntilshehearsthestartingpistolgooff,andthenacceleratesrapidlyuntilsheattainsaconstantvelocity.Shemaintainsthisvelocityuntilshecrossesthefinishline,andthensheslowsdowntoawalk,takingmoretimetoslowdownthanshedidtospeedupatthebeginningoftherace.Sketchavelocity-timeandaposition-timegraphtorepresenthermotion.Drawthemoneabovetheotheronthesametimescale.Indicateonyourp-tgraphwherethestartingblocksandfinishlineare.PositionTimeVelocityTimeStartingFinishblocksline41.CriticalThinkingDescribehowyoucouldcalculatetheaccelerationofanauto-mobile.Specifythemeasuringinstrumentsandtheproceduresthatyouwoulduse.Onepersonreadsastopwatchandcallsouttimeintervals.Anotherpersonreadsthespeedometerateachtimeandrecordsit.Plotspeedversustimeandfindtheslope.PracticeProblems3.3FreeFallpages72–75Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page7442.Aconstructionworkeraccidentallydropsabrickfromahighscaffold.a.Whatisthevelocityofthebrickafter4.0s?Sayupwardisthepositivedirection.v2f�vi�at,a��g��9.80m/sv2)(4.0s)f�0.0m/s�(�9.80m/s��39m/swhentheupwarddirectionispositiveb.Howfardoesthebrickfallduringthistime?12d�v��atit�2�0��1�2)(4.0s)2��(�9.80m/s2��78mThebrickfalls78m.43.Supposeforthepreviousproblemyouchooseyourcoordinatesystemsothattheoppositedirectionispositive.38SolutionsManualPhysics:PrinciplesandProblems
42Chapter3continueda.Whatisthebrick’svelocityafter4.0s?Nowthepositivedirectionisdownward.v2f�vi�at,a�g�9.80m/sv2)(4.0s)f�0.0m/s�(9.80m/s��39m/swhenthedownwarddirectionispositiveb.Howfardoesthebrickfallduringthistime?d�v�1�at2,a�g�9.80m/s2it�2�(0.0m/s)(4.0s)���1��(9.80m/s2)(4.0s)22��78mThebrickstillfalls78m.44.Astudentdropsaballfromawindow3.5mabovethesidewalk.Howfastisitmovingwhenithitsthesidewalk?v2�v2�2ad,a�gandvfii�0sovf��2�gd��(2)(9.8��0m/s2�)(3.5m)��8.3m/s45.Atennisballisthrownstraightupwithaninitialspeedof22.5m/s.Itiscaughtatthesamedistanceabovetheground.a.Howhighdoestheballrise?a��g,andatthemaximumheight,vf�0v2�v2�2adbecomesfiv2�2gdiv22i(22.5m/s)d�������25.8m2g(2)(9.80m/s2)b.Howlongdoestheballremainintheair?Hint:Thetimeittakestheballtoriseequalsthetimeittakestofall.Calculatetimetoriseusingvf�vi�at,witha��gandvf�0vi22.5m/st�������2.30sg9.80m/s2Thetimetofallequalsthetimetorise,sothetimetoremainintheairisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tair�2trise�(2)(2.30s)�4.60s46.YoudecidetoflipacointodeterminewhethertodoyourphysicsorEnglishhomeworkfirst.Thecoinisflippedstraightup.a.Ifthecoinreachesahighpointof0.25mabovewhereyoureleasedit,whatwasitsinitialspeed?Physics:PrinciplesandProblemsSolutionsManual39
43Chapter3continuedv2�v2�2a�dfivi��v�f2�2�g�dwherea��gandvf�0attheheightofthetoss,sovi��(0.0m��/s)2��(2)(9.80m/�s�2)(0.25m)��2.2m/sb.Ifyoucatchitatthesameheightasyoureleasedit,howmuchtimediditspendintheair?vf�vi�atwherea��gvi�2.2m/sandvf��2.2m/sv�vfit����g�2.2m/s�2.2m/s����2�9.80m/s�0.45sSectionReview3.3FreeFallpages72–75page7547.MaximumHeightandFlightTimeAccelerationduetogravityonMarsisaboutone-thirdthatonEarth.SupposeyouthrowaballupwardwiththesamevelocityonMarsasonEarth.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Howwouldtheball’smaximumheightcomparetothatonEarth?Atmaximumheight,vf�0,v2isod��,orthreetimeshigher.f�2gb.Howwoulditsflighttimecompare?12,orTimeisfoundfromd��gtf�2f2dt��f.Distanceismultipliedby3andgisdividedby3,f���gsotheflighttimewouldbethreetimesaslong.48.VelocityandAccelerationSupposeyouthrowaballstraightupintotheair.Describethechangesinthevelocityoftheball.Describethechangesintheaccelerationoftheball.40SolutionsManualPhysics:PrinciplesandProblems
44Chapter3continuedVelocityisreducedataconstantrateastheballtravelsupward.Atitshighestpoint,velocityiszero.Astheballbeginstodrop,thevelocitybeginstoincreaseinthenegativedirectionuntilitreachestheheightfromwhichitwasinitiallyreleased.Atthatpoint,theballhasthesamespeedithaduponrelease.Theaccelerationisconstantthroughouttheball’sflight.49.FinalVelocityYoursisterdropsyourhousekeysdowntoyoufromthesecondfloorwindow.Ifyoucatchthem4.3mfromwhereyoursisterdroppedthem,whatisthevelocityofthekeyswhenyoucatchthem?Upwardispositivev2�v2�2a�dwherea��giv��v�i2�2�g�d��(0.0m��/s)2��(2)(9.80m/�s�2)(�4.3m)��9.2m/s50.InitialVelocityAstudenttryingoutforthefootballteamkicksthefootballstraightupintheair.Theballhitshimonthewaybackdown.Ifittook3.0sfromthetimewhenthestudentpuntedtheballuntilhegetshitbytheball,whatwasthefootball’sinitialvelocity?Chooseacoordinatesystemwithupasthepositivedirectionandtheoriginatthepunter.Choosetheinitialtimeatthepuntandthefinaltimeatthetopofthefootball’sflight.vf�vi�atfwherea��gvi�vf�gtf�0.0m/s�(9.80m/s2)(1.5s)�15m/s51.MaximumHeightWhenthestudentinthepreviousproblemkickedthefoot-ball,approximatelyhowhighdidthefootballtravel?v2�v2�2a(�d)wherea��gfiv2�v2fi�d����2g(0.0m/s)2�(15m/s)2����(�2)(9.80m/s2)�11m52.CriticalThinkingWhenaballisthrownverticallyupward,itcontinuesupwardCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.untilitreachesacertainposition,andthenitfallsdownward.Atthathighestpoint,itsvelocityisinstantaneouslyzero.Istheballacceleratingatthehighestpoint?Deviseanexperimenttoproveordisproveyouranswer.Theballisaccelerating;itsvelocityischanging.Takeastrobephototomeasureitsposition.Fromphotos,calculatetheball’svelocity.Physics:PrinciplesandProblemsSolutionsManual41
45Chapter3continuedChapterAssessment3025ConceptMapping20page801553.Completethefollowingconceptmapusing10thefollowingsymbolsorterms:d,velocity,Velocity(m/s)5m/s2,v,m,acceleration.05101520253035Time(s)Quantitiesofmotion■Figure3-16Thecarstartsfromrestandincreasespositionvelocityaccelerationitsspeed.Asthecar’sspeedincreases,thedrivershiftsgears.dva57.Whatdoestheslopeofthetangenttothecurveonavelocity-timegraphmeasure?mm/sm/s2(3.1)instantaneousaccelerationMasteringConceptspage8058.Canacartravelingonaninterstatehighway54.Howarevelocityandaccelerationrelated?haveanegativevelocityandapositiveaccel-(3.1)erationatthesametime?Explain.CantheAccelerationisthechangeinvelocitycar’svelocitychangesignswhileitistravelingdividedbythetimeintervalinwhichitwithconstantacceleration?Explain.(3.1)occurs:itistherateofchangeofYes,acar’svelocityispositiveornega-velocity.tivewithrespecttoitsdirectionofmotionfromsomepointofreference.55.Giveanexampleofeachofthefollowing.OnedirectionofmotionisdefinedasCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(3.1)positive,andvelocitiesinthatdirectiona.anobjectthatisslowingdown,buthasareconsideredpositive.Theoppositeapositiveaccelerationdirectionofmotionisconsiderednega-tive;allvelocitiesinthatdirectionareifforwardisthepositivedirection,anegative.Anobjectundergoingpositivecarmovingbackwardatdecreasingaccelerationiseitherincreasingitsspeedvelocityinthepositivedirectionorb.anobjectthatisspeedingup,buthasareducingitsvelocityinthenegativenegativeaccelerationdirection.Acar’svelocitycanchangeinthesamecoordinatesystem,acarsignswhenexperiencingconstantmovingbackwardatincreasingacceleration.Forexample,itcanbespeedtravelingright,whiletheaccelerationistotheleft.Thecarslowsdown,stops,56.Figure3-16showsthevelocity-timegraphandthenstartsacceleratingtotheleft.foranautomobileonatesttrack.Describehowthevelocitychangeswithtime.(3.1)59.Canthevelocityofanobjectchangewhenitsaccelerationisconstant?Ifso,giveanexample.Ifnot,explain.(3.1)Yes,thevelocityofanobjectcanchangewhenitsaccelerationiscon-stant.Example:droppingabook.The42SolutionsManualPhysics:PrinciplesandProblems
46Chapter3continuedlongeritdrops,thefasteritgoes,butStudentanswerswillvary.Someexam-theaccelerationisconstantatg.plesareasteelball,arock,andaper-sonfallingthroughsmalldistances.60.Ifanobject’svelocity-timegraphisastraightlineparalleltothet-axis,whatcanyoucon-ApplyingConceptscludeabouttheobject’sacceleration?(3.1)pages80–81Whenthevelocity-timegraphisaline66.Doesacarthatisslowingdownalwayshaveparalleltothet-axis,theaccelerationisanegativeacceleration?Explain.zero.No,ifthepositiveaxispointsinthedirectionoppositethevelocity,the61.Whatquantityisrepresentedbytheareaaccelerationwillbepositive.underavelocity-timegraph?(3.2)thechangeindisplacement67.CroquetAcroquetball,afterbeinghitbyamallet,slowsdownandstops.Dothe62.Writeasummaryoftheequationsforvelocityandaccelerationoftheballhaveposition,velocity,andtimeforanobjectthesamesigns?experiencingmotionwithuniformNo,theyhaveoppositesigns.acceleration.(3.2)(vv68.Ifanobjecthaszeroacceleration,doesitf�i)t��f�ameanitsvelocityiszero?Giveanexample.vNo,a�0whenvelocityisconstant.f�vi�atfvvv�����v��f��i69.Ifanobjecthaszerovelocityatsome22instant,isitsaccelerationzero?Givean�d�v��texample.vvf�iNo,aballrollinguphillhaszerovelocity����t2attheinstantitchangesdirection,butassumingti�0,thenitsaccelerationisnonzero.�t�tf70.Ifyouweregivenatableofvelocitiesofanvf�viobjectatvarioustimes,howwouldyoufind�d�����tf2outwhethertheaccelerationwasconstant?Drawavelocity-timegraphandsee63.Explainwhyanaluminumballandasteelwhetherthecurveisastraightlineorballofsimilarsizeandshape,dropped�vcalculateaccelerationsusinga����fromthesameheight,reachthegroundat�tthesametime.(3.3)andcomparetheanswerstoseeiftheyarethesame.Allobjectsacceleratetowardthegroundatthesamerate.71.ThethreenotchesinthegraphinFigure3-16occurwherethedriverchanged64.Givesomeexamplesoffallingobjectsforgears.Describethechangesinvelocityandwhichairresistancecannotbeignored.accelerationofthecarwhileinfirstgear.Is(3.3)theaccelerationjustbeforeagearchangeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Studentanswerswillvary.Somelargerorsmallerthantheaccelerationjustexamplesaresheetsofpaper,afterthechange?Explainyouranswer.parachutes,leaves,andfeathers.65.Givesomeexamplesoffallingobjectsforwhichairresistancecanbeignored.(3.3)Physics:PrinciplesandProblemsSolutionsManual43
47Chapter3continuedVelocityincreasesrapidlyatfirst,thenmoreslowly.Accelerationisgreatestatthebeginningbutisreducedasvelocityincreases.Eventually,itisnec-essaryforthedrivertoshiftintosecondgear.Theaccelerationissmallerjustbeforethegearchangebecausetheslopeislessatthatpointonthegraph.Oncethedrivershiftsandthegearsengage,accelerationandtheslopeofthecurveincrease.72.UsethegraphinFigure3-16anddeterminethetimeintervalduringwhichtheaccelerationislargestandthetimeintervalduringwhichtheaccelerationissmallest.Theaccelerationislargestduringanintervalstartingatt�0andlasting1about��s.Itissmallestbeyond33s.273.Explainhowyouwouldwalktoproduceeachoftheposition-timegraphsinFigure3-17.CFDEABGHDisplacementDisplacementTimeTime■Figure3-17Walkinthepositivedirectionataconstantspeed.Walkinthepositivedirectionatanincreasingspeedforashorttime;keepwalkingatamoderatespeedfortwicethatamountoftime;slowdownoverashorttimeandstop;remainstopped;andturnaroundandrepeattheprocedureuntiltheoriginalpositionisreached.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.74.Drawavelocity-timegraphforeachofthegraphsinFigure3-18.DisplacementDisplacementDisplacementTimeTimeTime■Figure3-18TimeVelocityVelocityVelocityTimeTime44SolutionsManualPhysics:PrinciplesandProblems
48Chapter3continued75.Anobjectshotstraightuprisesfor7.0sb.IftheballonJupiterwerethrownwithbeforeitreachesitsmaximumheight.Asec-aninitialvelocitythatisthreetimesondobjectfallingfromresttakes7.0stogreater,howwouldthisaffectyourreachtheground.Comparetheanswertoparta?displacementsofthetwoobjectsduringthisWithvf�0,thevaluedfisdirectlytimeinterval.proportionaltothesquareofinitialBothobjectstraveledthesamedis-(3v22�i)velocity,v��.tance.Theobjectthatisshotstraighti.Thatis,df�vf2gupwardrisestothesameheightfromOnEarth,aninitialvelocitythreewhichtheotherobjectfell.timesgreaterresultsinaballrisingninetimeshigher.OnJupiter,how-76.TheMoonThevalueofgontheMoonisever,theheightofninetimeshigherone-sixthofitsvalueonEarth.wouldbereducedtoonlythreea.Wouldaballthatisdroppedbyantimeshigherbecauseofdf’sinverseastronauthitthesurfaceoftheMoonrelationshiptoagthatisthreewithagreater,equal,orlesserspeedtimesgreater.thanthatofaballdroppedfromthesameheighttoEarth?78.RockAisdroppedfromacliffandrockBisthrownupwardfromthesameposition.TheballwillhittheMoonwithalesserspeedbecausetheaccelera-a.Whentheyreachthegroundatthetionduetogravityislessonthebottomofthecliff,whichrockhasaMoon.greatervelocity?b.Wouldittaketheballmore,less,orRockBhitsthegroundwithaequaltimetofall?greatervelocity.Theballwilltakemoretimetofall.b.Whichhasagreateracceleration?Theyhavethesameacceleration,77.JupiterTheplanetJupiterhasaboutthreetheaccelerationduetogravity.timesthegravitationalaccelerationofEarth.c.Whicharrivesfirst?SupposeaballisthrownverticallyupwardrockAwiththesameinitialvelocityonEarthandonJupiter.NeglecttheeffectsofJupiter’sMasteringProblemsatmosphericresistanceandassumethatgravityistheonlyforceontheball.3.1Accelerationpages81–82a.HowdoesthemaximumheightreachedbytheballonJupitercomparetotheLevel1maximumheightreachedonEarth?79.Acarisdrivenfor2.0hat40.0km/h,thenforanother2.0hat60.0km/hinthesameTherelationshipbetweendandgis(v2�v2)direction.fianinverseone:d��.f�2ga.Whatisthecar’saveragevelocity?Ifgincreasesbythreetimes,orTotaldistance:(v2�v2)80.0km�120.0km�200.0kmfi1d��,d��.f�2(3g)fchangesby3totaltimeis4.0hours,so,Therefore,aballonJupiterwould�d200.0km1km/hv��������5.0�10Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1�t4.0hrisetoaheightof��thatonEarth.3b.Whatisthecar’saveragevelocityifitisdriven1.0�102kmateachofthetwospeeds?Physics:PrinciplesandProblemsSolutionsManual45
49Chapter3continuedTotaldistanceis2.03102km;1.0�102km1.0�102kmtotaltime������40.0km/h60.0km/h�4.2h�d2.0�102kmsov��������t4.2h�48km/h80.Findtheuniformaccelerationthatcausesacar’svelocitytochangefrom32m/sto96m/sinan8.0-speriod.�va�����tv�v21����t96m/s�32m/s2����8.0m/s8.0s81.Acarwithavelocityof22m/sisaccelerateduniformlyattherateof1.6m/s2for6.8s.Whatisitsfinalvelocity?vf�vi�atf�22m/s�(1.6m/s2)(6.8s)�33m/s82.RefertoFigure3-19tofindtheaccelerationofthemovingobjectateachofthefollowingtimes.30.0Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.20.010.0Velocity(m/s)0.05.010.015.020.025.030.0Time(s)■Figure3-19a.duringthefirst5.0softravel�va�����t30.0m/s�0.0m/s����5.0s�6.0m/s2b.between5.0sand10.0s�va�����t30.0m/s�30.0m/s����5.0s�0.0m/s246SolutionsManualPhysics:PrinciplesandProblems
50Chapter3continuedc.between10.0sand15.0s�va�����t20.0m/s�30.0m/s����5.0s��2.0m/s2d.between20.0sand25.0s�va�����t0.0m/s�20.0m/s����5.0s��4.0m/s2Level283.Plotavelocity-timegraphusingtheinformationTable3-4inTable3-4,andanswerthefollowingquestions.Velocityv.Time16.0Time(s)Velocity(m/s)12.00.004.001.008.008.002.0012.04.00Time(s)3.0014.00.00Velocity(m/s)2.004.006.008.0010.012.04.0016.0�4.005.0016.0�8.006.0014.07.0012.0a.Duringwhattimeintervalistheobject8.008.00speedingup?Slowingdown?9.004.00speedingupfrom0.0sto4.0s;slowing10.00.00downfrom5.0sto10.0s11.0�4.00b.Atwhattimedoestheobjectreversedirection?12.0�8.00at10.0sc.Howdoestheaverageaccelerationoftheobjectintheintervalbetween0.0sand2.0sdifferfromtheaverageaccelerationintheintervalbetween7.0sand12.0s?�va�����tbetween0.0sand2.0s:12.0m/s�4.0m/s2a������4.0m/s2.0s�0.0sbetween7.0sand12.0s:a�������8.0m/s�12.0m/s�4.0m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12.0s�7.0sPhysics:PrinciplesandProblemsSolutionsManual47
51Chapter3continued84.Determinethefinalvelocityofaproton3.2MotionwithConstantAccelerationthathasaninitialvelocityof2.35�105m/spage82andthenisaccelerateduniformlyinanLevel1electricfieldattherateof�1.10�1012m/s287.RefertoFigure3-19tofindthedistancefor1.50�10�7s.traveledduringthefollowingtimeintervals.vf�vi�atfa.t�0.0sandt�5.0s�2.35�105m/s�1AreaI���bh(�1.10�1012m/s2)(1.50�10�7s)2�7.0�104m/s���1��(5.0s)(30.0m/s)2Level3�75m85.SportsCarsMarcoislookingforausedb.t�5.0sandt�10.0ssportscar.HewantstobuytheonewiththeAreaII�bhgreatestacceleration.CarAcangofrom0�(10.0s�5.0s)(30.0m/s)m/sto17.9m/sin4.0s;carBcanacceleratefrom0m/sto22.4m/sin3.5s;andcarC�150mcangofrom0to26.8m/sin6.0s.Rankthec.t�10.0sandt�15.0sthreecarsfromgreatestaccelerationtoleast,1specificallyindicatinganyties.AreaIII�AreaIV�bh���bh2CarA:�(15.0s�10.0s)(20.0m/s)�a�����v���17.9m/s�0m/s�4.5m/s21�t4.0s�0.0s��2��(15.0s�10.0s)(10.0m/s)CarB:�125ma�����v���22.4m/s�0m/s�6.4m/s2d.t�0.0sandt�25.0s�t3.5s�0.0sAreaI�AreaII�CarC:(AreaIII�AreaIV)�AreaV�IV�v26.8m/s�0m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a��������4.5m/s�75m�150m�125m��t6.0s�0.0s1CarBhasthegreatestaccelerationofbh���bh26.4m/s2.Usingsignificantdigits,carAandcarCtiedat4.5m/s2.�75m�150m�125m�(20.0s�15.0s)(20.0m/s)�86.SupersonicJetAsupersonicjetflyingat1145m/sexperiencesuniformaccelerationat����(25.0s�20.0s)2therateof23.1m/s2for20.0s.�5.0�102ma.Whatisitsfinalvelocity?vf�vi�atfLevel2�145m/s�(23.1m/s2)(20.0s)88.Adragsterstartingfromrestacceleratesat49m/s2.Howfastisitgoingwhenithas�607m/straveled325m?b.Thespeedofsoundinairis331m/s.v2�v2�2a(dWhatistheplane’sspeedintermsoffif�di)thespeedofsound?v�2�f��vi2�a(df��di)607m/sN���331m/s�1.83timesthespeedofsound48SolutionsManualPhysics:PrinciplesandProblems
52Chapter3continued���(0.0m/s)�2��(2)(49�m/s2)(325m���0.0�m)�180m/s89.Acarmovesat12m/sandcoastsupahillwithauniformaccelerationof�1.6m/s2.a.Whatisitsdisplacementafter6.0s?12d��atf�vitf�2f�(12m/s)(6.0s)���1��(�1.6m/s2)(6.0s)22�43mb.Whatisitsdisplacementafter9.0s?12d��atf�vitf�2f�(12m/s)(9.0s)���1��2)(9.0s)2(�1.6m/s2�43mThecarisonthewaybackdownthehill.Theodometerwillshowthatthecartraveled45mupthehill�2mbackdown�47m.90.RaceCarAracecarcanbeslowedwithaconstantaccelerationof�11m/s2.a.Ifthecarisgoing55m/s,howmanymeterswillittravelbeforeitstops?v2�v2�2adfifv2�v2fid��f�2a(0.0m/s)2�(�55m/s)2����(2)(�11m/s2)�1.4�102mb.Howmanymeterswillittaketostopacargoingtwiceasfast?v2�v2�2adfifv2�v2fid��f�2a(0.0m/s)2�(110m/s)2�����550m,(2)(�11m/s2)whichisabout4timeslongerthanwhengoinghalfthespeed.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.91.Acaristraveling20.0m/swhenthedriverseesachildstandingontheroad.Shetakes0.80storeact,thenstepsonthebrakesandslowsat7.0m/s2.Howfardoesthecargobeforeitstops?reactiondisplacementdr�(20.0m/s)(0.80s)�16mPhysics:PrinciplesandProblemsSolutionsManual49
53Chapter3continuedv2�v2thereforefid��f�2a1t�0and��a2policet�vspeeder�0brakingdisplacement2vspeeder(0.0m/s)2�(20.0m/s)2t���d���apoliceb�(2)(�7.0m/s2)�29m��(2)(30.�0m/s)7.0m/s2totaldisplacementis�8.6sdr�db�16m�29m�45mAftert�8.6s,thepolicecar’svelocityLevel3was92.AirplaneDeterminethedisplacementofavf�vi�atplanethatexperiencesuniformaccelerationfrom66m/sto88m/sin12s.�0.0m/s�(7.0m/s2)(8.6s)(vf�vi)t�6.0�101m/sd��f�v�t�2(88m/s�66m/s)(12s)95.RoadBarrierThedriverofacargoing����90.0km/hsuddenlyseesthelightsofabar-2rier40.0mahead.Ittakesthedriver0.75s�9.2�102mtoapplythebrakes,andtheaverageacceler-ationduringbrakingis�10.0m/s2.93.Howfardoesaplaneflyin15swhileitsvelocityischangingfrom145m/stoa.Determinewhetherthecarhitsthe75m/satauniformrateofacceleration?barrier.Thecarwilltravel(vvd�v�t�f��i)t�d�vt�(25.0m/s)(0.75s)2�18.8m(Roundoffattheend.)(75m/s�145m/s)(15m/s)�����beforethedriverappliesthebrakes.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2Convertkm/htom/s.�1.6�103m(90.0km/h)(1000m/km)v���94.PoliceCarAspeedingcaristravelingatai�3600s/hconstantspeedof30.0m/swhenitpassesa�25.0m/sstoppedpolicecar.Thepolicecaracceler-v2�v2�2a(datesat7.0m/s2.Howfastwillitbegoingfif�di)whenitcatchesupwiththespeedingcar?v2�v2d��fidf��2adispeeder�vspeedert(0.0m/s)2�(25.0m/s)212�����18.8mdpolice�vipolicet���apolicet(2)(�10.0m/s2)212�5.0�101m,yesithitsthebarrierv��aspeedert�vipolicet�2policetsincevipolice�0then12v��aspeedert�2policet0�1�a2�v�2policetspeedert10�t��2�apolicet�vspeeder�50SolutionsManualPhysics:PrinciplesandProblems
54Chapter3continuedb.Whatisthemaximumspeedatwhichvf�vi�atfwherea��gthecarcouldbemovingandnothitthe�vbarrier40.0mahead?Assumethatthei�gtfaccelerationdoesn’tchange.�0.0m/s�(9.80m/s2)(8.0s)d��78m/s(downward)total�dconstant�ddeceleratingb.Whatisthestone’sdisplacementduring�40.0mthistime?dc�vt�(0.75s)vChoosethecoordinatesystemto02�v2�v2havetheoriginwherethestoneisd���d��2a2(�10.0m/s2)atrestandpositivetobeupward.v212wherea��g���20.0m/s2df�vit��2�atfv212�v��gt40m�(0.75s)v���2it�2f20.0m/sv2�(15m/s)v�800m2/s2�0�0.0m���1��(9.80m/s2)(8.0s)22Usingthequadraticequation:2m��3.1�10v�22m/s(Thesenseoftheprob-lemexcludesthenegativevalue.)99.Abagisdroppedfromahoveringhelicopter.Thebaghasfallenfor2.0s.Whatisthebag’s3.3FreeFallvelocity?Howfarhasthebagfallen?page82Velocity:Level1v96.Astudentdropsapennyfromthetopofaf�vi�atfwherea��gtoweranddecidesthatshewillestablisha�vi�gtfcoordinatesysteminwhichthedirectionofthepenny’smotionispositive.Whatisthe�0.0m/s�(9.80m/s2)(2.0s)signoftheaccelerationofthepenny?��2.0�101m/sThedirectionofthevelocityispositive,Displacement:andvelocityisincreasing.Therefore,1d��at2wherea��gtheaccelerationisalsopositive.f�vitf�2f1297.Supposeanastronautdropsafeatherfrom�vitf��2�gt1.2mabovethesurfaceoftheMoon.Ifthe�0.0m��1�2)(2.0s)2accelerationduetogravityontheMoonis��(9.80m/s21.62m/s2downward,howlongdoesittake��2.0�101mthefeathertohittheMoon’ssurface?d2�(0m/s)t2f�vitf�atff�atfLevel22df(2)(1.2m)100.Youthrowaballdownwardfromawindowtf����a������(1.62m/s2)�1.2sataspeedof2.0m/s.Howfastwillitbemovingwhenithitsthesidewalk2.5m98.Astonethatstartsatrestisinfreefallbelow?for8.0s.ChooseacoordinatesystemwiththeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Calculatethestone’svelocityafter8.0s.positivedirectiondownwardandtheoriginatthepointwheretheballleavesyourhand.Physics:PrinciplesandProblemsSolutionsManual51
55Chapter3continuedv2�v2�2adfifwherea�gvf���vi2�2�gdf��(2.0m�/s)�2��(2)(9.�80m/s�2)(2.5�m)�7.3m/s101.Ifyouthrowtheballinthepreviousproblemupinsteadofdown,howfastwillitbemovingwhenithitsthesidewalk?Choosethesamecoordinatesystem.v2�v2�2adfifwherea�gvf���vi2�2�gdf��(2.0m�/s)�2��(2)(9.�80m/s�2)(2.5�m)�7.3m/s(dfisthedisplacement,notthetotaldistancetraveled.)Level3102.BeanbagYouthrowabeanbagintheairandcatchit2.2slater.a.Howhighdiditgo?Chooseacoordinatesystemwiththeupwarddirectionpositiveandtheoriginatthepointwherethebeanbagleftyourhand.Assumethatyoucatchthebeanbagatthesameplacewhereyouthrewit.Therefore,thetimetoreachthemaximumheightishalfofthetimeintheair.Choosetitobethetimewhenthebeanbagleftyourhandandtftobethetimeatthemaximumheight.Eachformulathatyouknowincludesvi,soyouwillhavetoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.calculatethatfirst.vf�vi�atfwherea��gvi�vf�gtf�0.0m/s�(9.80m/s2)(1.1s)�11m/sNowyoucanuseanequationthatincludesthedisplacement.d�1�at2wherea��gf�di�vitf�2f12�d��gti�vitf�2f�0.0m�(11m/s)(1.1s)���1��2)(1.1s)2(9.80m/s2�6.2mb.Whatwasitsinitialvelocity?vi�11m/s52SolutionsManualPhysics:PrinciplesandProblems
56Chapter3continuedvvMixedReviewd�i��ftf�v�tf�2fpages82–840.0m/s�4.0m/sLevel1������(4.0s)2103.Aspaceshipfarfromanystarorplanet�8.0mexperiencesuniformaccelerationfrom65.0m/sto162.0m/sin10.0s.Howfar106.Aweatherballoonisfloatingataconstantdoesitmove?heightaboveEarthwhenitreleasesapackChoosingacoordinatesystemwithofinstruments.theoriginatthepointwherethespeeda.Ifthepackhitsthegroundwithais65.0m/sandgivenvi�65.0m/s,velocityof�73.5m/s,howfardidthevf�162.0m/s,andtf�10.0sandpackfall?needingdf,weusetheformulawithv2�v2�2adfiftheaveragevelocity.v2�v21fidf�di���(vi�vf)tfdf��2a�21(�73.5m/s)2�(0.00m/s)2df�0��2�(65.0m/s�162.0m/s)(10.0s)�����2)(2)(�9.80m/s�1.14�103m��276m104.Figure3-20isastrobephotoofab.Howlongdidittakeforthepacktofall?horizontallymovingball.Whatinformationvf�vi�atfwherea��gaboutthephotowouldyouneedandwhatv�vmeasurementswouldyoumaketoestimatefit��f��gtheacceleration?�73.5m/s�0.00m/s�����9.80m/s2�7.50sLevel2■Figure3-20107.BaseballAbaseballpitcherthrowsafast-Youneedtoknowthetimebetweenballataspeedof44m/s.Theaccelerationflashesandthedistancebetweentheoccursasthepitcherholdstheballinhisfirsttwoimagesandthedistancehandandmovesitthroughanalmostbetweenthelasttwo.Fromthese,youstraight-linedistanceof3.5m.Calculategettwovelocities.Betweenthesetwotheacceleration,assumingthatitisvelocities,atimeintervaloftsecondsconstantanduniform.Comparethisaccel-occurred.Dividethedifferenceerationtotheaccelerationduetogravity.betweenthetwovelocitiesbyt.v2�v2�2adfif105.BicycleAbicycleacceleratesfrom0.0m/sv2�v2fito4.0m/sin4.0s.Whatdistancedoesita���2dftravel?(44m/s)2�02m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.����2.8�10(2)(3.5m)2.8�102m/s2���29,or29timesg9.80m/s2Physics:PrinciplesandProblemsSolutionsManual53
57Chapter3continued108.Thetotaldistanceasteelballrollsdownv2�v2�2adfifaninclineatvarioustimesisgiveninTable3-5.orv2�2adffv232Table3-5f(3.5�10m/s)a�����2d(2)(0.020m)Distancev.TimefTime(s)Distance(m)�3.1�108m/s20.00.0b.Overwhattimeintervaldoestheaccelerationtakeplace?1.02.0(v2.08.0f�vi)td���23.018.02df(2)(0.020m)4.032.0t��v��v����3.5�103m/s�0.0m/sfi5.050.0�11�10�6sa.Drawaposition-timegraphofthe�11microsecondsmotionoftheball.Whensettingup110.SledsRocket-poweredsledsareusedtotheaxes,usefivedivisionsforeachtesttheresponsesofhumanstoaccelera-10moftravelonthed-axis.Usefivetion.Startingfromrest,onesledcanreachdivisionsfor1softimeonthet-axis.aspeedof444m/sin1.80sandcanbe50.0broughttoastopagainin2.15s.a.Calculatetheaccelerationofthesled40.0whenstarting,andcompareittothe30.0magnitudeoftheaccelerationduetogravity,9.80m/s2.20.0Position(m)v�v�v2110.0a��������t�tCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Topof0.01.02.03.04.05.0����444m/s�0.00m/sincline1.80sTime(s)�247m/s2b.Calculatethedistancetheballhasrolledattheendof2.2s.247m/s2���25timesg9.80m/s2After2.2secondstheballhasrolledapproximately10m.b.Findtheaccelerationofthesledasitisbrakingandcompareittothemagni-109.Engineersaredevelopingnewtypesoftudeoftheaccelerationduetogravity.gunsthatmightsomedaybeusedtov�v�v21launchsatellitesasiftheywerebullets.a�������t�tOnesuchguncangiveasmallobjecta0.00m/s�444m/svelocityof3.5km/swhilemovingit����2.15sthroughadistanceofonly2.0cm.��207m/s2a.Whataccelerationdoesthegungive207m/s2thisobject?���21timesg9.80m/s254SolutionsManualPhysics:PrinciplesandProblems
58Chapter3continued111.Thevelocityofacarchangesoveran8.0-s1d���bh�bhtimeperiod,asshowninTable3-6.21Table3-6���2��(5.0s)(20.0m/s�0.0m/s)�Velocityv.Time(8.0s�5.0s)(20.0m/s)Time(s)Velocity(m/s)�110m0.00.0e.Findtheslopeofthelinebetween1.04.0t�0.0sandt�4.0s.Whatdoesthis2.08.0sloperepresent?3.012.04.016.0�v16.0m/s�0.00m/sa�������5.020.0�t4.0s�0.0s6.020.0�4.0m/s2,acceleration7.020.0f.Findtheslopeofthelinebetween8.020.0t�5.0sandt�7.0s.Whatdoesthisa.Plotthevelocity-timegraphoftheslopeindicate?motion.�v20.0m/s�20.0m/sa��������t7.0s�5.0s20.02,constantvelocity�0.0m/s16.012.0Level38.0112.Atruckisstoppedatastoplight.WhentheVelocity(m/s)lightturnsgreen,thetruckacceleratesat4.02.5m/s2.Atthesameinstant,acarpassesthetruckgoing15m/s.Whereandwhen0.01.02.03.04.05.06.07.08.0doesthetruckcatchupwiththecar?Time(s)Car:b.Determinethedisplacementofthecardf�di�vtfduringthefirst2.0s.dcar�di�vcartf�vcartfFindtheareaunderthev-tcurve.�0�(15m/s)t1fd���bh2Truck:1�����(2.0s)(8.0m/s�0.0m/s)d�1�at22f�di�vitf�2f�8.0m12d��ac.Whatdisplacementdoesthecarhavetruck�2trucktfduringthefirst4.0s?�0�0��1�2)t2�2�(2.5m/sfFindtheareaunderthev-tcurve.Whenthetruckcatchesup,the1d���bh2displacementsareequal.��1�12Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�2�(4.0s)(16.0m/s�0.0m/s)vcartf��2�atrucktf�32m12�v0���a2trucktfcartfd.Whatisthedisplacementofthecarduringtheentire8.0s?10�t��af�2trucktf�vcar�Findtheareaunderthev-tcurve.Physics:PrinciplesandProblemsSolutionsManual55
59Chapter3continuedtherefore10.01t��af�0and2trucktf�vcar�05.02vcar0.0t��f�atruck�5.0FistDisplacement(cm)(2)(15m/s)0.0���2.5m/s�5.0�12s�10.0df�(15m/s)tfVelocity(m/s)�15.05.010.015.020.025.030.0�(15m/s)(12s)Time(ms)�180m■Figure3-22113.SafetyBarriersHighwaysafetyengineersa.Usethevelocity-timegraphtodescribebuildsoftbarriers,suchastheoneshownthemotionofGeorge’sfistduringtheinFigure3-21,sothatcarshittingthemfirst10ms.willslowdownatasaferate.ApersonThefistmovesdownwardatwearingasafetybeltcanwithstandanabout�13m/sforabout4ms.accelerationof�3.0�102m/s2.HowthickItthensuddenlycomestoahaltshouldbarriersbetosafelystopacarthat(accelerates).hitsabarrierat110km/h?b.Estimatetheslopeofthevelocity-timegraphtodeterminetheaccelerationofhisfistwhenitsuddenlystops.�v0m/s�(�13m/s)a��������t7.5ms�4.0ms�3.7�103m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.Expresstheaccelerationasamultipleofthegravitationalacceleration,■Figure3-21g�9.80m/s2.(110km/h)(1000m/km)3.7�103m/s22vi�����3600s/h31m/s��2�3.8�109.80m/svf2�vi2�2adfTheaccelerationisabout380g.withv2��2add.Determinetheareaunderthevelocity-f�0m/s,vif,ortimecurvetofindthedisplacementof�v22thefistinthefirst6ms.Comparethisi�(31m/s)d������f�2a(2)(�3.0�102m/s2)withtheposition-timegraph.�1.6mthickTheareacanbeapproximatedbyarectangle:114.KarateTheposition-timeandvelocity-(�13m/s)(0.006s)��8cmtimegraphsofGeorge’sfistbreakingaThisisinagreementwiththewoodenboardduringkaratepracticeareposition-timegraphwherethehandshowninFigure3-22.movesfrom�8cmto0cm,foranetdisplacementof�8cm.56SolutionsManualPhysics:PrinciplesandProblems
60Chapter3continued115.CargoAhelicopterisrisingat5.0m/schangethedistancethecartmoves,whenabagofitscargoisdropped.Thebecausetheaccelerationisalwaysbagfallsfor2.0s.thesame:g.a.Whatisthebag’svelocity?117.AnalyzeandConcludeWhichhasthevf�vi�atfwherea��ggreateracceleration:acarthatincreasesits�vspeedfrom50km/hto60km/h,orabikei�gtfthatgoesfrom0km/hto10km/hinthe�5.0m/s�(9.80m/s2)(2.0s)sametime?Explain.��15m/sv�vfib.Howfarhasthebagfallen?a����td�1�at2wherea��gf�vitf�2f60km/h�50km/hForcar,a�����t12�v��gtitf�2f10km/h����t�(5.0m/s)(2.0s)�10km/h�0km/h12)(2.0s)2Forbike,a�����t����(9.80m/s210km/h��1.0�101m����tThebaghasfallen1.0�101mThechangeinvelocityisthesame.c.Howfarbelowthehelicopteristhebag?118.AnalyzeandConcludeAnexpresstrain,travelingat36.0m/s,isaccidentallyside-Thehelicopterhasrisentrackedontoalocaltraintrack.Thed2)(2.0s)expressengineerspotsalocaltrainexactlyf�vitf�(5.0m/s1.00�102maheadonthesametrackand�1.0�101mtravelinginthesamedirection.ThelocalThebagis1.0�101mbelowtheengineerisunawareofthesituation.Theoriginand2.0�101mbelowtheexpressengineerjamsonthebrakesandhelicopter.slowstheexpresstrainataconstantrateof3.00m/s2.IfthespeedofthelocalThinkingCriticallytrainis11.0m/s,willtheexpresstrainpage84beabletostopintime,orwilltherebe116.ApplyCBLsDesignalabtomeasuretheacollision?Tosolvethisproblem,takedistanceanacceleratedobjectmovesoverthepositionoftheexpresstrainwhentime.Useequaltimeintervalssothatyoutheengineerfirstsightsthelocaltraincanplotvelocityovertimeaswellasdis-asapointoforigin.Next,keepingintance.Apulleyattheedgeofatablewithamindthatthelocaltrainhasexactlyamassattachedisagoodwaytoachieve1.00�102mlead,calculatehowfareachuniformacceleration.Suggestedmaterialstrainisfromtheoriginattheendoftheincludeamotiondetector,CBL,labcart,12.0sitwouldtaketheexpresstrainstring,pulley,C-clamp,andmasses.tostop(accelerateat�3.00m/s2fromGeneratedistance-timeandvelocity-time36m/sto0m/s).Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.graphsusingdifferentmassesonthea.Onthebasisofyourcalculations,pulley.Howdoesthechangeinmassaffectwouldyouconcludethatacollisionyourgraphs?willoccur?Students’labswillvary.StudentsExpress:shouldfindthatachangeinthemassd�1�at2f�vitf�2fovertheedgeofthetablewillnot�(36.0m/s)(12.0s)�Physics:PrinciplesandProblemsSolutionsManual57
61Chapter3continued��1��(�3.00m/s2)(12.0s)22�432m�216m�216mLocal:d2f�di�vitf�atf�100m�(11.0m/s)(12.0s)�0�232mOnthisbasis,nocollisionwilloccur.b.Thecalculationsthatyoumadedonotallowforthepossibilitythatacolli-sionmighttakeplacebeforetheendofthe12srequiredfortheexpresstraintocometoahalt.Tocheckthis,takethepositionoftheexpresstrainwhentheengineerfirstsightsthelocaltrainasthepointoforiginandcalcu-latethepositionofeachtrainattheendofeachsecondafterthesighting.Makeatableshowingthedistanceofeachtrainfromtheoriginattheendofeachsecond.Plotthesepositionsonthesamegraphanddrawtwolines.Useyourgraphtocheckyouranswertoparta.t(s)d(Local)d(Express)d(m)(m)2501111352122662003133954144120150Local51551451006166162Position(m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Express71771795081881929199203t1021021024681012Time(s)1122121512232216Theycollidebetween6and7s.WritinginPhysicspage84119.ResearchanddescribeGalileo’scontributionstophysics.Studentanswerswillvary.AnswersshouldincludeGalileo’sexperimentsdemonstratinghowobjectsaccelerateastheyfall.AnswersmightincludehisuseofatelescopetodiscoverthemoonsofJupiterandtheringsofSaturn,andhisrelianceonexperimentalresultsratherthanauthority.58SolutionsManualPhysics:PrinciplesandProblems
62Chapter3continued120.ResearchthemaximumaccelerationaPosition-TimeGraphhumanbodycanwithstandwithoutblack-400ingout.Discusshowthisimpactsthedesignofthreecommonentertainmentor300transportationdevices.200Answerswillvary.Becausehumanscanexperiencenegativeeffects,like100blackouts,thedesignersofrollerPosition(m)coastersneedtostructurethedown-0wardslopesinsuchawaythatthecoasterdoesnotreachaccelerations�100thatcauseblackouts.Likewise,engi-284610neersworkingonbullettrains,eleva-Time(s)tors,orairplanesneedtodesigntheMotionDiagramsysteminsuchawaythatallowstheobjecttorapidlyacceleratetohighspeeds,withoutcausingthepassen-gerstoblackout.ChallengeProblempage75CumulativeReviewYounoticeawaterballoonfallpastyourclass-page84roomwindow.Youestimatethatittookthe121.Solvethefollowingproblems.Expressyourballoonabouttsecondstofallthelengthoftheanswersinscientificnotation.(Chapter1)windowandthatthewindowisaboutymetersa.6.2�10�4m�5.7�10�3mhigh.Supposetheballoonstartedfromrest,approximatelyhowhighabovethetopofthe6.3�10�3mwindowwasitreleased?Youranswershouldbeb.8.7�108km�3.4�107mintermsoft,y,g,andnumericalconstants.8.4�108kmDownispositive.Workthisproblemintwoc.(9.21�10�5cm)(1.83�108cm)stages.Stage1isfallingthedistanceDto1.69�104cm2thetopofthewindow.Stage2isfallingthed.(2.63�10�6m)/(4.08�106s)distanceyfromthetopofthewindowtothebottomofthewindow.6.45�10�13m/sStage1:theoriginisatthetopofthefall.122.Theequationbelowdescribesthemotionv2�v2�2a(df1i1f1�di1)ofanobject.Createthecorrespondingposition-timegraphandmotiondiagram.�0�2g(D�0)Thenwriteaphysicsproblemthatcouldvf1��2�gDbesolvedusingthatequation.Becreative.d�(35.0m/s)t�5.0m(Chapter2)Stage2:theoriginisatthetopofthewindow.Graphandmotiondiagramindicate12d��atf2�di1�vi1tf2�2f2constantvelocitymotionwithavelocityof35.0m/sandinitialposition12y�0�v��gtf1t�2of�5.0m.AnswerswillvaryfortheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.create-a-problempart.12�0���2�gD�(t)���gt2ygt�2�gD������t21ygt2D����������2gt2Physics:PrinciplesandProblemsSolutionsManual59
63
64CHAPTER4ForcesinOneDimension3.AcablepullsacrateataconstantspeedPracticeProblemsacrossahorizontalsurface.Thesurfacepro-4.1ForceandMotionvidesaforcethatresiststhecrate’smotion.pages87–95Systempage89Foreachofthefollowingsituations,specifythesystemanddrawamotiondiagramandafree-bodydia-gram.Labelallforceswiththeiragents,andindicatethedirectionoftheaccelerationandofthenetforce.�xDrawvectorsofappropriatelengths.vvvv1.Aflowerpotfallsfreelyfromawindowsill.(Ignoreanyforcesduetoairresistance.)a�0SystemFfrictionFpulloncrateoncrateFnet�0�y4.Aropeliftsabucketataconstantspeed.(Ignoreairresistance.)vaFnet�yFEarth’smassonflowerpotvFropeonbucket2.AskydiverfallsdownwardthroughtheairSystematconstantvelocity.(Theairexertsanvupwardforceontheperson.)a�0Fnet�0v�yvFairresistancevondiverFEarth’smassonbucketva�0Fnet�05.Aropelowersabucketataconstantspeed.vSystemFEarth’smass(Ignoreairresistance.)ondiver�yvFropeonbucketvSystemva�0Fnet�0vCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.FEarth’smassonbucketPhysics:PrinciplesandProblemsSolutionsManual61
65Chapter4continuedpage9310.InertiaCanyoufeeltheinertiaofapencil?6.Twohorizontalforces,225Nand165N,Ofabook?Ifyoucan,describehow.areexertedonacanoe.IftheseforcesareYes,youcanfeeltheinertiaofeitherappliedinthesamedirection,findthenetobjectbyusingyourhandtogiveeitherhorizontalforceonthecanoe.objectanacceleration;thatis,trytoF2Nchangetheobjectsvelocity.net�225N�165N�3.90�10inthedirectionofthetwoforces11.Free-BodyDiagramDrawafree-bodydia-gramofabagofsugarbeingliftedbyyour7.Ifthesametwoforcesasintheprevioushandataconstantspeed.Specificallyidentifyproblemareexertedonthecanoeinoppo-thesystem.Labelallforceswiththeiragentssitedirections,whatisthenethorizontalandmakethearrowsthecorrectlengths.forceonthecanoe?Besuretoindicatethedirectionofthenetforce.F1Nnet�225N�165N�6.0�10Fhandonbaginthedirectionofthelargerforce8.ThreeconfusedsleighdogsaretryingtopullasledacrosstheAlaskansnow.Alutiapullseastwithaforceof35N,Sewardalsoa�0pullseastbutwithaforceof42N,andbigSugarKodiakpullswestwithaforceof53N.Whatisthenetforceonthesled?Identifyeastaspositiveandthesledasthesystem.SystemFEarth’smassonbagFnet�FAlutiaonsled�FSewardonsled�12.DirectionofVelocityIfyoupushabookFintheforwarddirection,doesthismeanitsKodiakonsledvelocityhastobeforward?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�35N�42N�53NNo,itcouldbemovingbackwardand�24Nyouwouldbereducingthatvelocity.Fnet�24Neast13.Free-BodyDiagramDrawafree-bodydia-gramofawaterbucketbeingliftedbyaropeSectionReviewatadecreasingspeed.Specificallyidentify4.1ForceandMotionthesystem.Labelallforceswiththeiragentsandmakethearrowsthecorrectlengths.pages87–95page959.ForceIdentifyeachofthefollowingaseithera,b,orc:weight,mass,inertia,thepushofahand,thrust,resistance,airresis-Fropeonbuckettance,springforce,andacceleration.a.acontactforceb.afieldforceac.notaforceweight(b),mass(c),inertia(c),pushofahand(a),thrust(a),resistance(a),Systemairresistance(a),springforce(a),accel-FEarth’smassonbucketeration(c)62SolutionsManualPhysics:PrinciplesandProblems
66Chapter4continued14.CriticalThinkingAforceof1Nisthe18.InFigure4-8,theblockhasamassofonlyforceexertedonablock,andtheaccel-1.2kgandthespherehasamassof3.0kg.erationoftheblockismeasured.WhentheWhatarethereadingsonthetwoscales?sameforceistheonlyforceexertedona(Neglectthemassesofthescales.)secondblock,theaccelerationisthreetimesaslarge.Whatcanyouconcludeaboutthemassesofthetwoblocks?Becausem�F/aandtheforcesarethesame,themassofthesecondblockisone-thirdthemassofthefirstblock.PracticeProblems4.2UsingNewton’sLawspages96–101■Figure4-8page97Bottomscale:Identifythesphereasthe15.Youplaceawatermelononaspringscaleatsystemandupaspositive.thesupermarket.Ifthemassofthewatermel-Fnet�Fscaleonsphere�onis4.0kg,whatisthereadingonthescale?FThescalereadstheweightofthewater-Earth’smassonsphere�ma�0melon:Fscaleonsphere�FEarth’smassonsphereF2)�39Ng�mg�(4.0kg)(9.80m/s�msphereg16.Kamariaislearninghowtoice-skate.She2)�(3.0kg)(9.80m/swantshermothertopullheralongsothatshehasanaccelerationof0.80m/s2.If�29NKamaria’smassis27.2kg,withwhatforceTopscale:Identifytheblockasthesys-doeshermotherneedtopullher?(Neglecttemandupaspositive.anyresistancebetweentheiceandFnet�Ftopscaleonblock�Kamaria’sskates.)F2)�22NFbottomscaleonblock�net�ma�(27.2kg)(0.80m/sFEarth’smassonblock17.TaruandReikosimultaneouslygraba�ma�00.75-kgpieceofropeandbegintuggingonitinoppositedirections.IfTarupullswithFtopscaleonblock�Fbottomscaleonblock�aforceof16.0Nandtheropeacceleratesawayfromherat1.25m/s2,withwhatFEarth’smassonblockforceisReikopulling?�Fbottomscaleonblock�IdentifyReiko’sdirectionaspositivemblockgandtheropeasthesystem.�29N�(1.2kg)Fnet�FRiekoonrope�FTaruonrope�ma(9.80m/s2)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.FRiekoonrope�ma�FTaruonrope�41N�(0.75kg)(1.25m/s2)�16.0N�17NPhysics:PrinciplesandProblemsSolutionsManual63
67Chapter4continuedpage100c.Itspeedsupat2.00m/s2whilemoving19.OnEarth,ascaleshowsthatyouweighdownward.585N.Acceleratingdownward,a.Whatisyourmass?soa��2.00m/s2Thescalereads585N.SincethereisFnoacceleration,yourweightequalsscale�Fnet�Fgthedownwardforceofgravity:�ma�mgFg�mg�m(a�g)Fg585N�(75.0kg)(�2.00m/s2�som������59.7kgg9.80m/s29.80m/s2)b.WhatwouldthescalereadontheMoon(g�1.60m/s2)?�585Nd.Itmovesdownwardatconstantspeed.Onthemoon,gchanges:Constantspeed,soFg�mgMoona�0andFnet�0�(59.7kg)(1.60m/s2)Fscale�Fg�mg�95.5N�(75.0kg)(9.80m/s2)20.UsetheresultsfromExampleProblem2to�735Nanswerquestionsaboutascaleinaneleva-e.Itslowstoastopataconstantmagni-toronEarth.Whatforcewouldbeexertedtudeofacceleration.bythescaleonapersoninthefollowingConstantacceleration�a,thoughsituations?thesignofadependsonthedirec-a.Theelevatormovesatconstantspeed.tionofthemotionthatisending.Constantspeed,soa�0andFFscale�Fnet�FgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.net�0.�ma�mgFscale�Fg�(75.0kg)(a)��mg�(75.0kg)(9.80m/s2)(75.0kg)(9.80m/s2)�735N�(75.0kg)(a)�735Nb.Itslowsat2.00m/s2whilemovingupward.Slowingwhilemovingupward,soa��2.00m/s2Fscale�Fnet�Fg�ma�mg�m(a�g)�(75.0kg)(�2.00m/s2�9.80m/s2)�585N64SolutionsManualPhysics:PrinciplesandProblems
68Chapter4continuedSectionReviewConstantVelocityFscale4.2UsingNewton’sLawspages96–101page10121.LunarGravityComparetheforceholdinga10.0-kgrockonEarthandontheMoon.FgTheaccelerationduetogravityontheapparentweight�realweightMoonis1.62m/s2.ToholdtherockonEarth:SlowingWhileRising/FSpeedingUpWhileDescendingnet�FEarthonrock�Fholdonrock�0FscaleFholdonrock�FEarthonrock�mgEarth�(10.0kg)(9.80m/s2)�98.0NFgToholdtherockontheMoon:apparentweight�realweightFnet�FMoononrock�Fholdonrock�0FSpeedingUpWhileRising/holdonrock�FMoononrock�mgMoonSlowingWhileDescending�(10.0kg)(1.62m/s2)Fscale�16.2N22.RealandApparentWeightYoutakearideinafastelevatortothetopofatallbuildingandridebackdownwhilestandingonabathroomscale.DuringwhichpartsoftheFgridewillyourapparentandrealweightsbeapparentweight�realweightthesame?Duringwhichpartswillyourapparentweightbelessthanyourreal23.AccelerationTecle,withamassof65.0kg,weight?Morethanyourrealweight?Sketchisstandingbytheboardsatthesideofanfree-bodydiagramstosupportyouranswers.ice-skatingrink.HepushesofftheboardsApparentweightandrealweightarethewithaforceof9.0N.Whatishisresultingsamewhenyouaretravelingeitheruporacceleration?downataconstantvelocity.ApparentIdentifyTecleasthesystemandtheweightislessthanrealweightwhenthedirectionawayfromtheboardsaselevatorisslowingwhilerisingorspeed-positive.Theicecanbetreatedasaingupwhiledescending.Apparentresistance-freesurface.weightisgreaterwhenspeedingupwhilerisingorslowingwhilegoingFnet�FboardsonTecle�madown.Fa���boardsonTeclem9.0NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��65.0kg�0.14m/s2awayfromtheboardsPhysics:PrinciplesandProblemsSolutionsManual65
69Chapter4continued24.MotionofanElevatorYouareridinginupwardforceduetoairresistanceontheanelevatorholdingaspringscalewithaparachute.Theupwardacceleration1-kgmasssuspendedfromit.Youlookatcausesthedriver’sdownwardvelocitytothescaleandseethatitreads9.3N.What,decrease.Newton’ssecondlawsaysthatifanything,canyouconcludeabouttheanetforceinacertaindirectionwillelevator’smotionatthattime?resultinanaccelerationinthatdirectionIftheelevatorisstationaryormoving(Fnet�ma).ataconstantvelocity,thescaleshould27.CriticalThinkingYouhaveajobatameatread9.80N.Becausethescalereadsawarehouseloadinginventoryontotrucksforlighterweight,theelevatormustbeshipmenttogrocerystores.Eachtruckhasaacceleratingdownward.Tofindtheweightlimitof10,000Nofcargo.Youpushexactacceleration:identifyupasposi-eachcrateofmeatalongalow-resistancetiveandthe1-kgmassasthesystem.rollerbelttoascaleandweighitbeforeFnet�Fscaleon1kg�movingitontothetruck.However,rightFafteryouweigha1000-Ncrate,thescaleEarth’smasson1kg�mabreaks.DescribeawayinwhichyoucouldFa������scaleon1kg�FEarth’smasson1kgapplyNewton’slawstofigureoutthemapproximatemassesoftheremainingcrates.9.3N�9.80NAnswersmayvary.Onepossibleanswer���1kgisthefollowing:Youcanneglectresis-��0.5m/s2tanceifyoudoallyourmaneuveringon2downwardtherollerbelt.Becauseyouknowthe�0.5m/sweightofthe1000Ncrate,youcanuseitasyourstandard.Pullonthe1000N25.MassMarcosisplayingtug-of-warwithhiscratewithaparticularforcefor1s,catusingastuffedtoy.Atoneinstantduringestimateitsvelocity,andcalculatethethegame,Marcospullsonthetoywithaaccelerationthatyourforcegavetoit.forceof22N,thecatpullsintheoppositeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Next,pullonacrateofunknownmassdirectionwithaforceof19.5N,andthetoyexperiencesanaccelerationof6.25m/s2.withasclosetothesameforceasyoucanfor1s.Estimatethecrate’svelocityWhatisthemassofthetoy?andcalculatetheaccelerationyourIdentifythetoyasthesystemandtheforcegavetoit.Theforceyoupulleddirectiontowardhiscatasthepositivewithoneachcratewillbethenetforcedirection.ineachcase.Fnet�FMarcosontoy�Fcatontoy�maFnet1000-Ncrate�FnetunknowncrateFMarcosontoy�Fcatontoy(1000N)(am�����1000-Ncrate)�(munk)(aunk)a(1000N)(a22N�19.5Nm���1000-Ncrate)���unk�a6.25m/s2unk�0.40kg26.AccelerationAskydiverfallsataconstantspeedinthespread-eagleposition.Afterheopenshisparachute,istheskydiveracceler-ating?Ifso,inwhichdirection?ExplainyouranswerusingNewton’slaws.Yes,forawhilethediverisacceleratingupwardbecausethereisanadditional66SolutionsManualPhysics:PrinciplesandProblems
70Chapter4continued31.AsuitcasesitsonastationaryairportluggagePracticeProblemscart,asinFigure4-13.Drawafree-body4.3InteractionForcesdiagramforeachobjectandspecificallyindi-pages102–107cateanyinteractionpairsbetweenthetwo.page10428.Youliftarelativelylightbowlingballwithyourhand,acceleratingitupward.Whataretheforcesontheball?Whatforcesdoestheballexert?Whatobjectsaretheseforcesexertedon?Theforcesontheballaretheforceofyourhandandthegravitationalforceof■Figure4-13Earth’smass.TheballexertsaforceonyourhandandagravitationalforceonSuitcaseCartEarth.AlltheseforcesareexertedonFsurfaceoncartyourhand,ontheball,oronEarth.FcartonsuitcaseFEarth’smass29.Abrickfallsfromaconstructionscaffold.oncartIdentifyanyforcesactingonthebrick.AlsoFsuitcaseoncartFEarth’smassidentifyanyforcesthatthebrickexertsandonsuitcasetheobjectsonwhichtheseforcesareexerted.(Airresistancemaybeignored.)page106Theonlyforceactingonthebrickisthe32.YouarehelpingtorepairaroofbyloadinggravitationalattractionofEarth’smass.equipmentintoabucketthatworkershoistThebrickexertsanequalandoppositetotherooftop.IftheropeisguaranteednotforceonEarth.tobreakaslongasthetensiondoesnotexceed450Nandyoufillthebucketuntilit30.Youtossaballupintheair.Drawafree-hasamassof42kg,whatisthegreatestbodydiagramfortheballwhileitisstillaccelerationthattheworkerscangivethemovingupward.Identifyanyforcesactingbucketastheypullittotheroof?ontheball.AlsoidentifyanyforcesthattheIdentifythebucketasthesystemandballexertsandtheobjectsonwhichtheseupaspositive.forcesareexerted.Fnet�Fropeonbucket�FEarth’smassonbucketFEarth’smassonball�maFTheonlyforceactingontheballistheropeonbucket�FEarth’smassonbucketa������mforceofEarth’smassontheball,whenignoringairresistance.TheballexertsFropeonbucket�mg����anequalandoppositeforceonEarth.m450N�(42kg)(9.80m/s2)�����42kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.91m/s2Physics:PrinciplesandProblemsSolutionsManual67
71Chapter4continued33.DiegoandMikaaretryingtofixatireonForthebottomropewiththepositiveDiego’scar,buttheyarehavingtroubleget-directionupward:tingthetireloose.Whentheypulltogether,Fnet�Fbottomropeonbottomblock�Mikawithaforceof23NandDiegowithaforceof31N,theyjustbarelygetthetiretoFEarth’smassonbottomblockbudge.Whatisthemagnitudeofthestrength�ma�0oftheforcebetweenthetireandthewheel?FbottomropeonbottomblockIdentifythetireasthesystemandthedirectionofpullingaspositive.�FEarth’smassonbottomblockF�mgnet�Fwheelontire�FMikaontire�F�(5.0kg)(9.80m/s2)Diegoontire�ma�0�49NFForthetoprope,withthepositivedirec-wheelontire�FMikaontire�FDiegoontiretionupward:�23N�31NF�54Nnet�Ftopropeontopblock�Fbottomropeontopblock�FSectionReviewEarth’smassontopblock4.3InteractionForces�ma�0Fpages102–107topropeontopblockpage107�FEarth’smassontopblock�34.ForceHoldabookmotionlessinyourhandintheair.IdentifyeachforceanditsFbottomropeontopblockinteractionpaironthebook.�mg�FbottomropeontopblockTheforcesonthebookaredownwardCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.forceofgravityduetothemassof�(5.0kg)(9.80m/s2)�49NEarthandtheupwardforceofthehand.�98NTheforceofthebookonEarthandtheforceofthebookonthehandarethe37.TensionIfthebottomblockinproblemotherhalvesoftheinteractionpairs.36hasamassof3.0kgandthetensioninthetopropeis63.0N,calculatetheten-35.ForceLowerthebookfromproblem34atsioninthebottomropeandthemassofincreasingspeed.Doanyoftheforcesortheirthetopblock.interaction-pairpartnerschange?Explain.ForthebottomropewiththepositiveYes,theforceofthehandonthebookdirectionupward:becomessmallersothereisadown-Fwardacceleration.Theforceofthebooknet�Fbottomropeonbottomblock�alsobecomessmaller;youcanfeelFEarth’smassonbottomblockthat.Theinteractionpairpartners�ma�0remainthesame.Fbottomropeonbottomblock36.TensionAblockhangsfromtheceilingby�Famasslessrope.AsecondblockisattachedEarth’smassonbottomblocktothefirstblockandhangsbelowiton�(3.0kg)(9.80m/s2)anotherpieceofmasslessrope.Ifeachofthetwoblockshasamassof5.0kg,whatis�29Nthetensionineachrope?68SolutionsManualPhysics:PrinciplesandProblems
72Chapter4continuedForthetopmasswiththepositiveChapterAssessmentdirectionupward:FConceptMappingnet�Ftopropeontopblock�page112Fbottomropeontopblock�40.CompletethefollowingconceptmapusingFEarth’smassontopblockthefollowingtermandsymbols:normal,F�ma�0T,Fg.FEarth’smassontopblock�mgforce�Ftopropeontopblock�Fbottomropeontopblocktensionnormalgravitym�Ftopropeontopblock�Fbottomropeontopblock������gFTFNFg63.0N�29N���9.80m/s2�3.5kgMasteringConceptspage11238.NormalForcePolomahandsa13-kgbox41.Aphysicsbookismotionlessonthetopofto61-kgStephanie,whostandsonaplat-atable.Ifyougiveitahardpushwithyourform.Whatisthenormalforceexertedbyhand,itslidesacrossthetableandslowlytheplatformonStephanie?comestoastop.UseNewton’slawstoIdentifyStephanieasthesystemandanswerthefollowingquestions.(4.1)positivetobeupward.a.WhydoesthebookremainmotionlessFbeforetheforceofyourhandisapplied?net�FplatformonStephanie�AnobjectatresttendstostayatFboxonStephanie�restifnooutsideforceactsonit.FEarth’smassonStephanieb.WhydoesthebookbegintomovewhenFyourhandpusheshardenoughonit?platformonStephanieTheforcefromyourhandisgreater�FboxonStephanie�thananyopposingforcesuchasfric-Ftion.Withanetforceonit,thebookEarth’smassonStephanieslidesinthedirectionofthenetforce.�mboxg�mStephaniegc.Underwhatconditionswouldthebook�(13kg)(9.80m/s2)�(61kg)(9.80m/s2)remaininmotionataconstantspeed?�7.3�102NThebookwouldremaininmotionifthenetforceactingonitiszero.39.CriticalThinkingAcurtainpreventstwotug-of-warteamsfromseeingeachother.42.CyclingWhydoyouhavetopushharderOneteamtiesitsendoftheropetoatree.onthepedalsofasingle-speedbicycletoIftheotherteampullswitha500-Nforce,startitmovingthantokeepitmovingataCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.whatisthetension?Explain.constantvelocity?(4.1)Thetensionwouldbe500N.TheropeisAlargeforceisrequiredtoacceleratetheinequilibrium,sothenetforceonitismassofthebicycleandrider.Oncethezero.Theteamandthetreeexertequaldesiredconstantvelocityisreached,aforcesinoppositedirections.muchsmallerforceissufficienttoover-cometheever-presentfrictionalforces.Physics:PrinciplesandProblemsSolutionsManual69
73Chapter4continued43.Supposethattheaccelerationofanobjectis47.Arockisdroppedfromabridgeintoaval-zero.Doesthismeanthattherearenoley.Earthpullsontherockandacceleratesforcesactingonit?Giveanexamplesup-itdownward.AccordingtoNewton’sthirdportingyouranswer.(4.2)law,therockmustalsobepullingonEarth,No,itonlymeanstheforcesactingonityetEarthdoesnotseemtoaccelerate.arebalancedandthenetforceiszero.Explain.(4.3)Forexample,abookonatableisnotTherockdoespullonEarth,butEarth’smovingbuttheforceofgravitypullsenormousmasswouldundergoonlyadownonitandthenormalforceoftheminuteaccelerationasaresultofsuchtablepushesuponitandtheseforcesasmallforce.Thisaccelerationwouldarebalanced.goundetected.44.BasketballWhenabasketballplayerdrib-48.Ramonpushesonabedthathasbeenblesaball,itfallstothefloorandbouncespushedagainstawall,asinFigure4-17.up.Isaforcerequiredtomakeitbounce?Drawafree-bodydiagramforthebedandWhy?Ifaforceisneeded,whatistheagentidentifyalltheforcesactingonit.Makeainvolved?(4.2)separatelistofalltheforcesthatthebedYes,itsvelocitychangeddirection;appliestootherobjects.(4.3)thus,itwasacceleratedandaforceisrequiredtoacceleratethebasketball.Theagentisthefloor.45.Beforeaskydiveropensherparachute,shemaybefallingatavelocityhigherthantheterminalvelocitythatshewillhaveaftertheparachuteopens.(4.2)a.Describewhathappenstohervelocity■Figure4-17assheopenstheparachute.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.BecausetheforceofairresistanceFflooronbedsuddenlybecomeslarger,thevelocityofthediverdropssuddenly.b.Describetheskydiver’svelocityfromwhenherparachutehasbeenopenforatimeuntilsheisabouttoland.FwallonbedFRamononbedTheforceofairresistanceandthegravitationalforceareequal.Theirsumiszero,sothereisnolongeranyFgacceleration.Theskydivercontinuesdownwardataconstantvelocity.Forcesthatbedappliestootherobjects:46.Ifyourtextbookisinequilibrium,whatcanFyousayabouttheforcesactingonit?(4.2)bedonRamon,FbedonEarth,Fbedonfloor,Ifthebookisinequilibrium,thenetFbedonwallforceiszero.Theforcesactingonthebookarebalanced.70SolutionsManualPhysics:PrinciplesandProblems
74Chapter4continued49.Figure4-18showsablockinfourdifferent52.BaseballAsluggerswingshisbatandhitssituations.Rankthemaccordingtothemag-abaseballpitchedtohim.Drawfree-bodynitudeofthenormalforcebetweenthediagramsforthebaseballandthebatatblockandthesurface,greatesttoleast.themomentofcontact.Specificallyindi-Specificallyindicateanyties.(4.3)cateanyinteractionpairsbetweenthetwodiagrams.(4.3)FballonbatFbatteronbatFbatonballApplyingConceptspages112–11353.WhiplashIfyouareinacarthatisstruckfrombehind,youcanreceiveaseriousneck■Figure4-18injurycalledwhiplash.a.UsingNewton’slaws,explainwhatfromlefttoright:second>fourth>happenstocausesuchaninjury.third>firstThecarissuddenlyaccelerated50.Explainwhythetensioninamasslessropeforward.Theseatacceleratesyourisconstantthroughoutit.(4.3)body,butyourneckhastoacceler-ateyourhead.ThiscanhurtyourIfyoudrawafree-bodydiagramforanyneckmuscles.pointontherope,therewillbetwoten-sionforcesactinginoppositedirec-b.Howdoesaheadrestreducewhiplash?tions.Fnet�Fup�Fdown�ma�0Theheadrestpushesonyourhead,(becauseitismassless).Therefore,acceleratingitinthesamedirectionFup�Fdown.AccordingtoNewton’sasthecar.thirdlaw,theforcethattheadjoiningpieceofropeexertsonthispointis54.SpaceShouldastronautschoosepencilsequalandoppositetotheforcethatthiswithhardorsoftleadformakingnotesinpointexertsonit,sotheforcemustbespace?Explain.constantthroughout.Asoftleadpencilwouldworkbetterbecauseitwouldrequirelessforceto51.AbirdsitsontopofastatueofEinstein.makeamarkonthepaper.Themagni-Drawfree-bodydiagramsforthebirdandtudeoftheinteractionforcepaircouldthestatue.Specificallyindicateanyinterac-pushtheastronautawayfromthepaper.tionpairsbetweenthetwodiagrams.(4.3)FEarthonstatueFstatueonbirdCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Fg,birdFbirdonstatueFg,statuePhysics:PrinciplesandProblemsSolutionsManual71
75Chapter4continued55.Whenyoulookatthelabeloftheproduct58.Youtossaballstraightupintotheair.inFigure4-19togetanideaofhowmucha.Drawafree-bodydiagramfortheballattheboxcontains,doesittellyouitsmass,threepointsduringitsmotion:ontheweight,orboth?Wouldyouneedtomakewayup,attheverytop,andonthewayanychangestothislabeltomakeitcorrectdown.SpecificallyidentifytheforcesforconsumptionontheMoon?actingontheballandtheiragents.OnthewayupFEarth’smassonballAtthetopFEarth’smassonball■Figure4-19OnthewaydownTheouncestellyoutheweightinEnglishunits.Thegramstellyouthemassinmetricunits.ThelabelwouldneedtoFEarth’smassonballread“2oz”tobecorrectontheMoon.Thegramswouldremainunchanged.b.Whatisthevelocityoftheballattheverytopofthemotion?56.Fromthetopofatallbuilding,youdrop0m/stwotable-tennisballs,onefilledwithairc.Whatistheaccelerationoftheballatandtheotherwithwater.Bothexperiencethissamepoint?airresistanceastheyfall.Whichballreach-Becausetheonlyforceactingonitesterminalvelocityfirst?Dobothhittheisthegravitationalattractionofgroundatthesametime?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Earth,a�9.80m/s2.Thelighter,air-filledtabletennisballreachesterminalvelocityfirst.ItsmassMasteringProblemsislessforthesameshapeandsize,so4.1ForceandMotionthefrictionforceofupwardairresis-tancebecomesequaltothedownwardpage113forceofmgsooner.BecausetheforceLevel1ofgravityonthewater-filledtable-tennis59.Whatisthenetforceactingona1.0-kgballball(moremass)islarger,itsterminalinfree-fall?velocityislarger,anditstrikestheFnet�Fg�mggroundfirst.�(1.0kg)(9.80m/s2)57.Itcanbesaidthat1kgequals2.2lb.What�9.8Ndoesthisstatementmean?Whatwouldbetheproperwayofmakingthecomparison?ItmeansthatonEarth’ssurface,theweightof1kgisequivalentto2.2lb.Youshouldcomparemassestomassesandweightstoweights.Thus9.8Nequals2.2lb.72SolutionsManualPhysics:PrinciplesandProblems
76Chapter4continued60.SkatingJoyceandEfuaareskating.Joyce65.ThreeobjectsaredroppedsimultaneouslypushesEfua,whosemassis40.0-kg,withafromthetopofatallbuilding:ashotput,forceof5.0N.WhatisEfua’sresultinganair-filledballoon,andabasketball.acceleration?a.RanktheobjectsintheorderinwhichF�matheywillreachterminalvelocity,fromFfirsttolast.a��mballoon,basketball,shotput5.0Nb.Ranktheobjectsaccordingtotheorder��40.0kginwhichtheywillreachtheground,�0.12m/s2fromfirsttolast.shotput,basketball,balloon61.Acarofmass2300kgslowsdownataratec.Whatistherelationshipbetweenyourof3.0m/s2whenapproachingastopsign.answerstopartsaandb?WhatisthemagnitudeofthenetforceTheyareinversesofeachother.causingittoslowdown?F�ma66.Whatistheweightinpoundsofa100.0-N�(2300kg)(3.0m/s2)woodenshippingcase?1kg2.2lb�6.9�103N(100.0N)�������22lb9.80N1kg62.BreakingtheWishboneAfter67.Youplacea7.50-kgtelevisiononaspringThanksgiving,KevinandGamalusethescale.Ifthescalereads78.4N,whatistheturkey’swishbonetomakeawish.IfKevinaccelerationduetogravityatthatlocation?pullsonitwithaforce0.17NlargerthantheFg�mgforceGamalpullswithintheoppositedirec-Ftion,andthewishbonehasamassof13g,gg��mwhatisthewishbone’sinitialacceleration?78.4NF��a��7.50kgm0.17N�10.5m/s2���0.013kgLevel2�13m/s268.DragRacingA873-kg(1930-lb)dragster,startingfromrest,attainsaspeedof26.3m/s(58.9mph)in0.59s.4.2UsingNewton’sLawsa.Findtheaverageaccelerationofthepages113–114dragsterduringthistimeinterval.Level163.Whatisyourweightinnewtons?a���v�tF2)(m)g�mg�(9.80m/s(26.3m/s�0.0m/s)Answerswillvary.����0.59s64.MotorcycleYournewmotorcycleweighs�45m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2450N.Whatisitsmassinkilograms?b.WhatisthemagnitudeoftheaveragenetFg�mgforceonthedragsterduringthistime?Fg2450NF�mam�����g9.80m/s2�(873kg)(45m/s2)�2.50�102N�3.9�104NPhysics:PrinciplesandProblemsSolutionsManual73
77Chapter4continuedc.Assumethatthedriverhasamassofe.Itslowstoastopwhilemovingdown-68kg.Whathorizontalforcedoesthewardwithaconstantacceleration.seatexertonthedriver?DependsonthemagnitudeoftheF�ma�(68kg)(45m/s2)acceleration.3NF�3.1�10scale�Fg�Fslowing�mg�ma69.AssumethatascaleisinanelevatoronEarth.Whatforcewouldthescaleexerton�m(g�a)a53-kgpersonstandingonitduringthe�(53kg)(9.80m/s2�a)followingsituations?a.Theelevatormovesupataconstant70.Agrocerysackcanwithstandamaximumspeed.of230Nbeforeitrips.Willabagholding15kgofgroceriesthatisliftedfromtheFscale�Fgcheckoutcounteratanaccelerationof�mg7.0m/s2hold?2)UseNewton’ssecondlawF�(53kg)(9.80m/snet�ma.�5.2�102NIfFgroceries�230,thenthebagrips.b.Itslowsat2.0m/s2whilemovingFgroceries�mgroceriesagroceries�upward.mSlowswhilemovinguporspeedsgroceriesgupwhilemovingdown,�mgroceries(agroceries�g)Fscale�Fg�Fslowing�(15kg)(7.0m/s2�9.80m/s2)�mg�ma�250N�m(g�a)Thebagdoesnothold.�(53kg)(9.80m/s2�2.0m/s2)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.71.A0.50-kgguineapigisliftedupfromthe�4.1�102Nground.Whatisthesmallestforceneeded2whilemovingtoliftit?Describeitsresultingmotion.c.Itspeedsupat2.0m/sFdownward.lift�FgSlowswhilemovinguporspeeds�mgupwhilemovingdown,�(0.50kg)(9.80m/s2)Fscale�Fg�Fspeeding�4.9N�mg�maItwouldmoveataconstantspeed.�m(g�a)Level3�(53kg)(9.80m/s2�2.0m/s2)72.AstronomyOnthesurfaceofMercury,the�4.1�102Ngravitationalaccelerationis0.38timesitsvalueonEarth.d.Itmovesdownwardataconstantspeed.a.Whatwoulda6.0-kgmassweighonFscale�FgMercury?�mgFg�mg(0.38)�(53kg)(9.80m/s2)�(6.0kg)(9.80m/s2)(0.38)�5.2�102N�22N74SolutionsManualPhysics:PrinciplesandProblems
78Chapter4continuedb.Ifthegravitationalaccelerationonthe4.3InteractionForcessurfaceofPlutois0.08timesthatofpage114Mercury,whatwoulda7.0-kgmassLevel1weighonPluto?75.A6.0-kgblockrestsontopofa7.0-kgFg�mg(0.38)(0.08)block,whichrestsonahorizontaltable.2)(0.38)(0.08)a.Whatistheforce(magnitudeanddirec-�(7.0kg)(9.80m/stion)exertedbythe7.0-kgblockonthe�2.1N6.0-kgblock?F73.A65-kgdiverjumpsoffofa10.0-mtower.net�N�mga.Findthediver’svelocitywhenhehitsFN�F7-kgblockon6-kgblockthewater.�mgv2�v2�2gdfi�(6.0kg)(9.80m/s2)vi�0m/s�59N;thedirectionisupward.sovf��2�gdb.Whatistheforce(magnitudeanddirec-tion)exertedbythe6.0-kgblockonthe��2(9.80��m/s2)(10.0�m)�7.0-kgblock?�14.0m/sequalandoppositetothatinparta;b.Thedivercomestoastop2.0mbelowtherefore,59Ndownwardthesurface.Findthenetforceexertedbythewater.76.RainAraindrop,withmass2.45mg,fallsv2�v2�2adtotheground.Asitisfalling,whatmagni-fitudeofforcedoesitexertonEarth?�v2v�iFf�0,soa�2draindroponEarth�Fg�mgandF�ma�mv2�(0.00245kg)(9.80m/s2)��i2d�2N�2.40�10�(65kg)(14.0m/s)2����2(2.0m)77.A90.0-kgmananda55-kgmanhavea��3.2�103Ntug-of-war.The90.0-kgmanpullsontheropesuchthatthe55-kgmanacceleratesat0.025m/s2.Whatforcedoestheropeexert74.CarRacingAracecarhasamassof710kg.Itstartsfromrestandtravels40.0min3.0s.onthe90.0-kgman?Thecarisuniformlyacceleratedduringthesameinmagnitudeastheforcetheentiretime.Whatnetforceisexertedonit?ropeexertsonthe55-kgman:12F�ma�(55kg)(0.025m/s2)�1.4Nd�v�0t���2atSincev0�0,2da��andF�ma,sot2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2mdF��t2(2)(710kg)(40.0m)����(3.0s)2�6.3�103NPhysics:PrinciplesandProblemsSolutionsManual75
79Chapter4continuedLevel2Fnet�Fmiddleblockontopblock�78.Malelionsandhumansprinterscanbothaccelerateatabout10.0m/s2.IfatypicalFEarth’smassontopblocklionweighs170kgandatypicalsprinter�ma�0weighs75kg,whatisthedifferenceintheFforceexertedonthegroundduringaracemiddleblockontopblockbetweenthesetwospecies?�FEarth’smassontopblockUseNewton’ssecondlaw,Fnet�ma.�mtopblockgThedifferencebetweenF�(4.6kg)(9.80m/s2)lionandFhumanisF�45Nlion�Fhuman�mThenormalforceisbetweenthebottomlionalion�mhumanahumanandmiddleblock;themiddleblockis�(170kg)(10.0m/s2)�thesystem;upwardispositive.(75kg)(10.0m/s2)Fnet�Fbottomblockonmiddleblock��9.5�102NFtopblockonmiddleblock�F79.A4500-kghelicopteracceleratesupwardatEarth’smassonmiddleblock2.0m/s2.Whatliftforceisexertedbythe�ma�0aironthepropellers?Ftopblockonmiddleblockma�Fnet�Fappl�Fg�Fappl�mg�FmiddleblockontopblocksoFappl�ma�mg�m(a�g)Fbottomblockonmiddleblock�(4500kg)((2.0m/s2)��Fmiddleblockontopblock�(�9.8m/s2))FEarth’smassonmiddleblockCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�5.3�104N�Fmiddleblockontopblock�Level3mmiddleblockg80.Threeblocksarestackedontopofone�45N�(1.2kg)(9.80m/s2)another,asinFigure4-20.Thetopblockhasamassof4.6kg,themiddleonehasa�57Nmassof1.2kg,andthebottomonehasaThenormalforceisbetweenthebottommassof3.7kg.Identifyandcalculateanyblockandthesurface;thebottomblocknormalforcesbetweentheobjects.isthesystem;upwardispositive.Fnet�Fsurfaceonbottomblock�Fmiddleblockonbottomblock�FEarth’smassonbottomblock�ma�0■Figure4-20Thenormalforceisbetweenthetopandmiddleblocks;thetopblockisthesystem;upwardispositive.76SolutionsManualPhysics:PrinciplesandProblems
80Chapter4continuedFFsurfaceonbottomblockF�thrustthrust�ma,soa�m�Fmiddleblockonbottomblock�Fg�mgFEarth’smassonbottomblockFgm���Fgmiddleblockonbottomblock�mbottomblockgvf�vi�atandvi�0,so�57N�(3.7kg)(9.80m/s2)vft���a�93Nvf��F��thrust��MixedReviewmpages114–115vm�f��Level1Fthrust81.Thedragsterinproblem68completeda12d�402.3-m(0.2500-mi)runin4.936s.Ifthef�di�vit�2atcarhadaconstantacceleration,whatwasitsdi�vi�0,soaccelerationandfinalvelocity?12d�12f�2atd�f�di�vit�2at1Fthrustvfm2d���2����m����F��i�vi�0,sothrust2df1v2ma�������f�t22Fthrust(2)(402.3m)���22Fg(4.936s)vf����1g������33.02m/s22Fthrust1df�di��(vf�vi)t22.75�106N2(79.2m/s)��9.80�m/s2�1d������6.35�106Ni�vi�0,so22d�139mv�ff�t83.Thedragsterinproblem68crossedthefinish(2)(402.3m)���linegoing126.6m/s.Doestheassumption4.936sofconstantaccelerationholdtrue?What�163.0m/sotherpieceofevidencecouldyouusetodetermineiftheaccelerationwasconstant?Level282.JetA2.75�106-Ncatapultjetplaneis126.6m/sisslowerthanfoundinreadyfortakeoff.Ifthejet’senginessupplyproblem81,sotheaccelerationcannotaconstantthrustof6.35�106N,howmuchbeconstant.Further,theaccelerationrunwaywillitneedtoreachitsminimuminthefirst0.59swas45m/s2,nottakeoffspeedof285km/h?33.02m/s2.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1hv�f�(285km/h)(1000m/km)��3600s�79.2m/sPhysics:PrinciplesandProblemsSolutionsManual77
81Chapter4continued84.Supposea65-kgboyanda45-kggirlusea86.BaseballAsabaseballisbeingcaught,itsmasslessropeinatug-of-waronanicy,speedgoesfrom30.0m/sto0.0m/sinresistance-freesurfaceasinFigure4-21.about0.0050s.ThemassofthebaseballisIftheaccelerationofthegirltowardthe0.145kg.boyis3.0m/s2,findthemagnitudeofthea.Whatisthebaseball’sacceleration?accelerationoftheboytowardthegirl.va��f�vitf�ti0.0m/s�30.0m/s����0.0050s�0.0s��6.0�103m/s2?3.0m/s2b.Whatarethemagnitudeanddirectionoftheforceactingonit?F�ma�(0.145kg)(�6.0�103m/s2)■Figure4-21��8.7�102NF1,2��F1,2,som1a1��m2a2(oppositedirectionofthevelocityof�manda�2a2theball)1�m1c.Whatarethemagnitudeanddirection�(45kg)(3.0m/s2)oftheforceactingontheplayerwho����(65kg)caughtit?��2.1m/s2Samemagnitude,oppositedirection(indirectionofvelocityofball)85.SpaceStationPratishweighs588Nandisweightlessinaspacestation.IfshepushesLevel3offthewallwithaverticalaccelerationof87.AirHockeyAnair-hockeytableworksby3.00m/s2,determinetheforceexertedbypumpingairthroughthousandsoftinyCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thewallduringherpushoff.holesinatabletosupportlightpucks.Thisallowsthepuckstomovearoundoncush-UseNewton’ssecondlawtoobtainionsofairwithverylittleresistance.OneofPratish’smass,mPratish.UseNewton’sthesepuckshasamassof0.25kgandisthirdlawFA��FB�mAaA��mBaB.pushedalongbya12.0-Nforcefor9.0s.Fa.Whatisthepuck’sacceleration?gm�Pratish�gF�maFFwallonPratish��FPratishonwalla��m�mPratishaPratish12.0N��F0.25kggaPratish���g�48m/s2(588N)(3.00m/s2)b.Whatisthepuck’sfinalvelocity?����9.80m/s2vf�vi�at�1.80�102Nvi�0,sovf�at�(48m/s2)(9.0s)�4.3�102m/s78SolutionsManualPhysics:PrinciplesandProblems
82Chapter4continued88.Astudentstandsonabathroomscaleinan89.WeatherBalloonTheinstrumentsattachedelevatoratrestonthe64thfloorofabuild-toaweatherballooninFigure4-22haveaing.Thescalereads836N.massof5.0kg.Theballoonisreleasedanda.Astheelevatormovesup,thescaleread-exertsanupwardforceof98Nontheingincreasesto936N.Findtheacceler-instruments.ationoftheelevator.Fnet�Fg�FelevatorFelevator�Fnet�Fg�maFgm��,sog98NFnet�Fga���Fg��g5.0kgg(Fnet�Fg)���Fg■Figure4-22(9.80m/s2)(963N�836N)a.Whatistheaccelerationoftheballoon�����836Nandinstruments?�1.17m/s2Fnet�Fappl�Fgb.Astheelevatorapproachesthe74th�Fappl�mgfloor,thescalereadingdropsto782N.Whatistheaccelerationoftheelevator?�98N�(5.0kg)(�9.80m/s2)Fnet�Fg�Felevator��49N(up)Felevator�Fnet�Fg�maFneta��mFgm��,so�49Ng��5.0kgFnet�Fg��9.8m/s2a���Fg�g�b.Aftertheballoonhasacceleratedfor10.0s,theinstrumentsarereleased.g(Fnet�Fg)Whatisthevelocityoftheinstruments���Fgatthemomentoftheirrelease?(9.80m/s2)(782N�836N)v�at�����836N�(�9.8m/s2)(10.0s)��0.633m/s2��98m/s(up)c.Usingyourresultsfrompartsaandb,c.Whatnetforceactsontheinstrumentsexplainwhichchangeinvelocity,start-aftertheirrelease?ingorstopping,takesthelongertime.justtheinstrumentweight,�49NStopping,becausethemagnitudeofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(down)theaccelerationislessand�vt���aPhysics:PrinciplesandProblemsSolutionsManual79
83Chapter4continuedd.Whendoesthedirectionoftheinstru-91.Twoblocks,masses4.3kgand5.4kg,arements’velocityfirstbecomedownward?pushedacrossafrictionlesssurfacebyaThevelocitybecomesnegativeafterhorizontalforceof22.5N,asshowninitpassesthroughzero.Thus,useFigure4-23.vf�vi�gt,wherevf�0,or�vt��ig�(�98m/s)���(�9.80m/s2)�1.0�101safterrelease90.Whenahorizontalforceof4.5Nactsonablockonaresistance-freesurface,itpro-■Figure4-23ducesanaccelerationof2.5m/s2.Supposeasecond4.0-kgblockisdroppedontothea.Whatistheaccelerationoftheblocks?first.Whatisthemagnitudeoftheaccelera-Identifythetwoblockstogetherastionofthecombinationifthesameforcethesystem,andrightaspositive.continuestoact?AssumethatthesecondFnet�ma,andm�m1�m2blockdoesnotslideonthefirstblock.FF�ma���firstblockainitialm1�m2Fm�22.5Nfirstblock�a���initial4.3kg�5.4kgF�mbothblocksafinal�2.3m/s2totheright�(mfirstblock�msecondblock)afinalb.Whatistheforceofthe4.3-kgblockonthe5.4-kgblock?Fso,a����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.final�mIdentifythe5.4-kgblockasthefirstblock�msecondblocksystemandrightaspositive.F����FFnet�F4.3-kgblockon5.4-kgblock���masecondblockinitial�ma����4.5N2)�(5.4kg)(2.3m/s4.5N���4.0kg2.5m/s2�12Ntotheright�0.78m/s2c.Whatistheforceofthe5.4-kgblockonthe4.3-kgblock?AccordingtoNewton’sthirdlaw,thisshouldbeequalandoppositetotheforcefoundinpartb,sotheforceis12Ntotheleft.80SolutionsManualPhysics:PrinciplesandProblems
84Chapter4continued92.Twoblocks,oneofmass5.0kgandtheotherofmass3.0kg,aretiedtogetherwithamasslessropeasinFigure4-24.Thisropeisstrungoveramassless,resis-tance-freepulley.Theblocksarereleasedfromrest.Findthefollowing.a.thetensionintheropeb.theaccelerationoftheblocksHint:youwillneedtosolvetwosimultaneousequations.3.0kg5.0kg■Figure4-24Equation1comesfromafree-bodydiagramforthe5.0-kgblock.Downispositive.Fnet�FEarth’smasson5.0-kgblock�Fropeon5.0-kgblock�m5.0-kgblocka(1)Equation2comesfromafree-bodydiagramforthe3.0-kgblock.Upispositive.Fnet�Fropeon3.0-kgblock�FEarth’smasson3.0-kgblock�m3.0-kgblocka(2)Theforcesoftheropeoneachblockwillhavethesamemagnitude,becausethetensionisconstantthroughouttherope.CallthisforceT.FEarth’smasson5.0-kgblock�T�m5.0-kgblocka(1)T�FEarth’smasson3.0-kgblock�m3.0-kgblocka(2)Solveequation2forTandplugintoequation1:m5.0-kgblocka�FEarth’smasson5.0-kgblock�FEarth’smasson3.0-kgblock�m3.0-kgblockaFEarth’smasson5.0-kgblock�FEarth’smasson3.0-kgblocka�������m5.0-kgblock�m3.0-kgblock(m5.0-kgblock�m3.0-kgblock)g�����m3.0-kgblock�m5.0-kgblock(5.0kg�3.0kg)(9.80m/s2)�����3.0kg�5.0kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�2.4m/s2Physics:PrinciplesandProblemsSolutionsManual81
85Chapter4continuedSolveequation2forT:FormA,mAa�FT�mAgT�FEarth’smasson3.0-kgblock�FormB,mBa��FT�mBgm3.0-kgblockaFT�mBg�mBa�mB(g�a)�m3.0-kgblockg�m3.0-kgblockaSubstitutingintotheequationfor�m3.0-kgblock(g�a)mAgives�(3.0kg)(9.80m/s2�2.4m/s2)mAa�mBg�mBa�mAg�37Nor(mA�mB)a�(mB�mA)gmThinkingCriticallyThereforea�����B�mAgmA�mBpages115–1163.0kg�2.0kg93.FormulateModelsA2.0-kgmass,mA,�����2.0kg�3.0kganda3.0-kgmass,mB,areconnectedtoalightweightcordthatpassesoverafriction-(9.80m/s2)lesspulley.Thepulleyonlychangesthe2upward�2.0m/sdirectionoftheforceexertedbytherope.Thehangingmassesarefreetomove.94.UseModelsSupposethatthemassesinChoosecoordinatesystemsforthetwoproblem93arenow1.00kgand4.00kg.masseswiththepositivedirectionbeingFindtheaccelerationofthelargermass.upformAanddownformB.ma.Createapictorialmodel.a�����B�mAgmA�mB4.00kg�1.00kg������(9.80m/s2)1.00kg�4.00kg�x�5.88m/s2downwardmA95.InferTheforceexertedona0.145-kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.baseballbyabatchangesfrom0.0NtomB1.0�104Nin0.0010s,thendropsbacktozerointhesameamountoftime.Thebase-b.Createaphysicalmodelwithmotionballwasgoingtowardthebatat25m/s.andfree-bodydiagrams.a.Drawagraphofforceversustime.Whatistheaverageforceexertedontheballbythebat?FT�x1.0�104amAaFTmAg0.5�104mBForce(N)mBg0.00.51.01.52.0Time(ms)1c.WhatistheaccelerationofthesmallerF�ave�2Fpeakmass?14N)ma�F����(1.0�10netwheremisthetotalmass2beingaccelerated.�5.0�103N82SolutionsManualPhysics:PrinciplesandProblems
86Chapter4continuedb.Whatistheaccelerationoftheball?FT2�m2a�FT1Fnet5.0�103N2)�6.0Na������(4.0kg)(3.0m/sm0.145kg�18N�3.4�104m/s2c.Whatisthefinalvelocityoftheball,97.CritiqueUsingtheExampleProblemsinassumingthatitreversesdirection?thischapterasmodels,writeasolutiontovthefollowingproblem.Ablockofmassf�vi�at3.46kgissuspendedfromtwovertical��25m/s�(3.4�104m/s2)ropesattachedtotheceiling.Whatisthe(0.0020s)tensionineachrope?�43m/s96.ObserveandInferThreeblocksthatareTTconnectedbymasslessstringsarepulledalongafrictionlesssurfacebyahorizontal3.46kgforce,asshowninFigure4-25.FT1FT26.0kgFg4.0kg2.0kgm1AnalyzeandSketchtheProblemm3F�36.0Nm21Drawfree-bodydiagramsfortheblockandchooseupwardtobepositive■Figure4-25SolvefortheUnknowna.Whatistheaccelerationofeachblock?Known:Sincetheyallmovetogether,themblock�3.46kgaccelerationisthesameforall3blocks.Unknown:F�maFrope1onblock�Frope2onblock�?�(m2SolvefortheUnknown1�m2�m3)aUseNewton’ssecondlawtofindtheFa���tensionintheropesm1�m2�m3Fnet�2Frope1onblock�36N����2.0kg�4.0kg�6.0kgFEarth’smassonblock�3.0m/s2�ma�0b.WhatarethetensionforcesineachofFF���Earth’smassonblockthestrings?rope1onblock�2Hint:Drawaseparatefree-bodydiagrammgF�foreachblock.rope1onblock�2Fnet�ma(3.46kg)(9.80m/s2)����2F�FT2�m3aCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�17.0NFT2�FT1�m2aFT1�m1a�(2.0kg)(3.0m/s2)�6.0NPhysics:PrinciplesandProblemsSolutionsManual83
87Chapter4continued3EvaluatetheAnswerIdentifythemassasthesystemand•Aretheunitscorrect?Nisthecorrectupwardaspositive.unitforatension,sinceitisaforce.Fnet�Fscaleonmass�Fg�ma�0•Doesthesignmakesense?Theposi-Ftivesignindicatesthatthetensionisscaleonmass�Fgpullingupwards.Fscaleonmass�mg•Isthemagnituderealistic?WewouldPluto:Fscaleonmassexpectthemagnitudetobeonthesameorderastheblock’sweight.�(5.00kg)(0.30m/s2)�1.5N98.ThinkCriticallyBecauseofyourphysicsknowledge,youareservingasascientificMercury:Fscaleonmassconsultantforanewscience-fictionTV2)�(5.00kg)(3.7m/sseriesaboutspaceexploration.Inepisode3,theheroine,MistyMoonglow,hasbeen�19Naskedtobethefirstpersontorideinanew99.ApplyConceptsDevelopaCBLlab,usinginterplanetarytransportforuseinoursolaramotiondetector,thatgraphsthedistancesystem.Shewantstobesurethatthetrans-afree-fallingobjectmovesoverequalinter-portactuallytakeshertotheplanetsheisvalsoftime.Alsographvelocityversustime.supposedtobegoingto,sosheneedstoCompareandcontrastyourgraphs.Usingtakeatestingdevicealongwithhertoyourvelocitygraph,determinetheaccelera-measuretheforceofgravitywhenshetion.Doesitequalg?arrives.Thescriptwritersdon’twanthertojustdropanobject,becauseitwillbehardStudentlabswillvarywithequipmenttodepictdifferentaccelerationsoffallingavailableanddesigns.p-tgraphsandobjectsonTV.Theythinkthey’dlikesome-v-tgraphsshouldreflectuniformaccel-thinginvolvingascale.Itisyourjobtoeration.TheaccelerationshouldbedesignaquickexperimentMistycancon-closetog.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ductinvolvingascaletodeterminewhichplanetinoursolarsystemshehasarrivedWritinginPhysicson.Describetheexperimentandincludepage116whattheresultswouldbeforPluto100.ResearchNewton’scontributionstophysics(g�0.30m/s2),whichiswheresheissup-andwriteaone-pagesummary.Doyouthinkposedtogo,andMercury(g�3.70m/s2),histhreelawsofmotionwerehisgreatestwhichiswheresheactuallyendsup.accomplishments?Explainwhyorwhynot.Answerswillvary.HereisonepossibleAnswerswillvary.Newton’scontribu-answer:Sheshouldtakeaknownmass,tionsshouldincludehisworkonlightsay5.00-kg,withherandplaceitontheandcolor,telescopes,astronomy,lawsscale.Sincethegravitationalforceofmotion,gravity,andperhapsdependsuponthelocalaccelerationcalculus.Oneargumentinfavorofhisduetogravity,thescalewillreadadif-threelawsofmotionbeinghisgreatestferentnumberofnewtons,dependingaccomplishmentsisthatmechanicsisonwhichplanetsheison.Thefollowingbasedonthefoundationoftheselaws.analysisshowshowtofigureoutwhatHisadvancesintheunderstandingofthescalewouldreadonagivenplanet:theconceptofgravitymaybesuggest-edashisgreatestaccomplishmentinsteadofhisthreelawsofmotion.84SolutionsManualPhysics:PrinciplesandProblems
88Chapter4continued101.Review,analyze,andcritiqueNewton’sTaro’shousetoyours,whenshouldyoufirstlaw.Canweprovethislaw?Explain.expecttheskiertopassyourhouse?Besuretoconsidertheroleofresistance.(Chapter2)Answerswillvary.Newton’sfirstlawofdd�vt,ort��motioninvolvesanobjectwhosenetvforcesarezero.Iftheobjectisatrest,itd�5.2km�5.2�103mremainsatrest;ifitisinmotion,itwill1000m1hcontinuetomoveinthesamedirectionv�(8.0km/h)������1km3600sataconstantvelocity.Onlyaforceact-ingonanobjectatrestcancauseitto�2.2m/smove.Likewise,onlyaforceactingon5.2�103mt���anobjectinmotioncancauseitto2.2m/schangeitsdirectionorspeed.Thetwo�2.4�103scases(objectatrest,objectinmotion)�39mincouldbeviewedastwodifferentframesofreference.Thislawcanbedemon-Theskiershouldpassyourhouseatstrated,butitcannotbeproven.8:25�0:39�9:04A.M.102.Physicistsclassifyallforcesintofourfunda-104.Figure4-26isaposition-timegraphofmentalcategories:gravitational,electro-themotionoftwocarsonaroad.magnetic,strongnuclear,andweaknuclear.(Chapter3)Investigatethesefourforcesanddescribethesituationsinwhichtheyarefound.PositionofTwoCars12Answerswillvary.ThestrongnuclearBforcehasaveryshortrangeandiswhat6holdsprotonsandneutronstogetherinAthenucleusofanatom.TheweakDistance(m)02468nuclearforceismuchlessstrongthanthestrongnuclearforceandisinvolvedTime(s)inradioactivedecay.Theelectromagnet-■Figure4-26icforceisinvolvedinholdingatomsa.Atwhattime(s)doesonecarpasstheandmoleculestogetherandisbasedonother?theattractionofoppositecharges.3s,8sGravityisalong-rangeforcebetweentwoormoremasses.b.Whichcarismovingfasterat7.0s?carACumulativeReviewc.Atwhattime(s)dothecarshavethepage116samevelocity?103.Cross-CountrySkiingYourfriendis5strainingforacross-countryskiingrace,andd.OverwhattimeintervaliscarBspeed-youandsomeotherfriendshaveagreedtoingupallthetime?providehimwithfoodandwateralonghistrainingroute.Itisabitterlycoldday,sononenoneofyouwantstowaitoutsidelongere.OverwhattimeintervaliscarBslow-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thanyouhaveto.Taro,whosehouseistheingdownallthetime?stopbeforeyours,callsyouat8:25A.M.to�3sto10stellyouthattheskierjustpassedhishouseandisplanningtomoveatanaveragespeedof8.0km/h.Ifitis5.2kmfromPhysics:PrinciplesandProblemsSolutionsManual85
89Chapter4continued105.RefertoFigure4-26tofindthe2.Ittakestheglider1.3stopassthroughainstantaneousspeedforthefollowing:secondgate.Whatisthedistancebetween(Chapter3)thetwogates?a.carBat2.0s12d�f�di�vit�2at0m/sb.carBat9.0sLetdi�positionoffirstgate�0.0m�0m/sd�0.0m�(0.25m/s)(1.3s)�c.carAat2.0s���1(0.80m/s2)(1.3s)22�1m/s�1.0mChallengeProblem3.The0.40-Nforceisappliedbymeansofastringattachedtotheglider.Theotherendpage100ofthestringpassesoveraresistance-freeAnair-trackgliderpassesthroughaphotoelectricpulleyandisattachedtoahangingmass,gateataninitialspeedof0.25m/s.Asitpassesm.Howbigism?throughthegate,aconstantforceof0.40NisFg�mmassgappliedtothegliderinthesamedirectionasitsmotion.Thegliderhasamassof0.50kg.Fgm��1.Whatistheaccelerationoftheglider?mass�gF�ma0.40N���F9.80m/s2a��m�4.1�10�2kg0.40N��0.50kg4.Deriveanexpressionforthetension,T,in2thestringasafunctionofthemass,M,of�0.80m/stheglider,themass,m,ofthehangingCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mass,andg.T�mg�Ma86SolutionsManualPhysics:PrinciplesandProblems
90CHAPTER5ForcesinTwoDimensionsPracticeProblems5.1Vectorspages119–125page1211.Acarisdriven125.0kmduewest,then65.0kmduesouth.Whatisthemagnitudeofitsdisplacement?Solvethisproblembothgraphicallyandmathematically,andcheckyouranswersagainsteachother.2�A2�B2R125.0kmR���A2�B2�65.0km��(65.0��km)2�(125.0km��)2141km�141km2.Twoshopperswalkfromthedoorofthemalltotheircar,whichis250.0mdownalaneofcars,andthenturn90°totherightandwalkanadditional60.0m.Whatisthemagnitudeofthedisplacementoftheshoppers’carfromthemalldoor?Solvethisproblembothgraphicallyandmathematically,andcheckyouranswersagainsteachother.2�A2�B2RMall250.0mdoorR���A2�B2�60.0m257mCar��(250.0��m)2��(60.0�m)2�257m3.Ahikerwalks4.5kminonedirection,thenmakesa45°turntotherightandwalksanother6.4km.Whatisthemagnitudeofherdisplacement?R2�A2�B2�2ABcos�R��A�2�B�2�2AB�cos����(4.5k��m)2��(6.4k�m)2��2(4.5�km)(6.4km�)(cos�135°)��1.0�101km4.Anantiscrawlingonthesidewalk.Atonemoment,itismovingsouthadistanceof5.0mm.Itthenturnssouthwestandcrawls4.0mm.Whatisthemagnitudeoftheant’sdisplacement?R2�A2�B2�2ABcos�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.R���A2��B2��2ABcos����(5.0m�m)�2��(4.0m�m)2��2(5.0�mm)(�4.0mm)(co�s135�°)��8.3mmPhysics:PrinciplesandProblemsSolutionsManual87
91Chapter5continuedpage125Solveproblems5–10algebraically.Youmayalsochoosetosolvesomeofthemgraphicallytocheckyouranswers.5.Sudhirwalks0.40kminadirection60.0°westofnorth,thengoes0.50kmduewest.Whatishisdisplacement?Identifynorthandwestasthepositivedirections.d1W�d1sin��(0.40km)(sin60.0°)�0.35kmd1N�d1cos��(0.40km)(cos60.0°)�0.20kmd2W�0.50kmd2N�0.00kmRW�d1W�d2W�0.35km�0.50km�0.85kmRN�d1N�d2N�0.20km�0.00km�0.20kmR��R�W2��RN2��(0.85�km)�2��(0.20�km)2�0.87kmR�1W��tan���RN�10.85km�tan����0.20km�77°R�0.87kmat77°westofnorth6.AfuaandChrissyaregoingtosleepovernightintheirtreehouseandareCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.usingsomeropestopullupaboxcontainingtheirpillowsandblankets,whichhaveatotalmassof3.20kg.Thegirlsstandondifferentbranches,asshowninFigure5-6,andpullattheanglesandwiththeforcesindicated.Findthex-andy-componentsofthenetforceonthebox.Hint:Drawafree-bodydiagramsothatyoudonotleaveoutaforce.Identifyupandrightaspositive.FAonbox,x�FAonboxcos�A�(20.4N)(cos120°)■Figure5-6��10.2NFAonbox,y�FAonboxsin�A�(20.4N)(sin120°)�17.7NFConbox,x�FConboxcos�A�(17.7N)(cos55°)88SolutionsManualPhysics:PrinciplesandProblems
92Chapter5continued�10.2NFcombined�Frope1onswingcos��FConbox,y�FConboxsin�AFrope2onswingcos��(17.7N)(sin55°)�2Frope2onswingcos��14.5N�(2)(2.28N)(cos13.0°)Fg,x�0.0N�4.44NupwardFg,y��mg9.Couldavectoreverbeshorterthanoneof��(3.20kg)(9.80m/s2)itscomponents?Equalinlengthtooneof��31.4Nitscomponents?Explain.FItcouldneverbeshorterthanoneofitsnetonbox,x�FAonbox,x�components,butifitliesalongeitherFConbox,x�Fg,xthex-ory-axis,thenoneofitscompo-nentsequalsitslength.��10.2N�10.2N�0.0N�0.0N10.Inacoordinatesysteminwhichthex-axisisFnetonbox,y�FAonbox,y�east,forwhatrangeofanglesisthex-compo-nentpositive?Forwhatrangeisitnegative?FConbox,y�Fg,yThex-componentispositiveforangles�17.7N�14.5N�31.4Nlessthan90°andforanglesgreater�0.8Nthan270°.It’snegativeforanglesgreaterthan90°butlessthan270°.Thenetforceis0.8Nintheupwarddirection.7.Youfirstwalk8.0kmnorthfromhome,thenSectionReviewwalkeastuntilyourdisplacementfromhome5.1Vectorsis10.0km.Howfareastdidyouwalk?pages119–125Theresultantis10.0km.Usingthepage125PythagoreanTheorem,thedistanceeast11.Distancev.DisplacementIsthedistanceisthatyouwalkequaltothemagnitudeofR2�A2�B2,soyourdisplacement?GiveanexamplethatB��R�2�A�2supportsyourconclusion.22Notnecessarily.Forexample,youcould��(10.0��km)��(8.0�km)walkaroundtheblock(onekmper�6.0kmside).Yourdisplacementwouldbezero,butthedistancethatyouwalkwouldbe8.Achild’sswingisheldupbytworopestied4kilometers.toatreebranchthathangs13.0°fromthevertical.Ifthetensionineachropeis2.28N,12.VectorDifferenceSubtractvectorKfromwhatisthecombinedforce(magnitudeandvectorL,showninFigure5-7.direction)ofthetworopesontheswing?Theforcewillbestraightup.BecauseCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.theanglesareequal,thehorizontalforceswillbeequalandoppositeandcancelout.ThemagnitudeofthisverticalforceisPhysics:PrinciplesandProblemsSolutionsManual89
93Chapter5continued16.CriticalThinkingAboxismovedthrough5.0onedisplacementandthenthroughasec-onddisplacement.Themagnitudesofthe�4.0M37.0°Ktwodisplacementsareunequal.Couldthedisplacementshavedirectionssuchthattheresultantdisplacementiszero?Supposetheboxwasmovedthroughthreedisplace-6.0Lmentsofunequalmagnitude.Couldthe■Figure5-7resultantdisplacementbezero?Support6.0�(�4.0)�10.0totherightyourconclusionwithadiagram.No,butiftherearethree13.ComponentsFindthecomponentsofdisplacements,thesumcanvectorM,showninFigure5-7.bezeroifthethreevectorsMx�mcos�formatrianglewhenthey�(5.0)(cos37.0°)areplacedtip-to-tail.Also,thesumofthreedisplace-�4.0totherightmentscanbezerowithoutMy�msin�formingatriangleifthesumoftwo�(5.0)(sin37.0°)displacementsinonedirectionequals�3.0upwardthethirdintheoppositedirection.14.VectorSumFindthesumofthethreevectorsshowninFigure5-7.PracticeProblemsRx�Kx�Lx�Mx5.2Friction��4.0�6.0�4.0pages126–130�6.0page128Ry�Ky�Ly�My17.Agirlexertsa36-NhorizontalforceassheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pullsa52-Nsledacrossacementsidewalk�0.0�0.0�3.0atconstantspeed.Whatisthecoefficientof�3.0kineticfrictionbetweenthesidewalkandR��R�x2��Ry2themetalsledrunners?Ignoreairresistance.F��6.0�2��3.02N�mg�52N�6.7Sincethespeedisconstant,thefrictionforceequalstheforceexertedbytheR�1ygirl,36N.��tan��R��xFf��kFN�13�tan����F6fso���k�F�27°NR�6.7at27°��36�N52N15.CommutativeOperationsTheorderin�0.69whichvectorsareaddeddoesnotmatter.Mathematicianssaythatvectoradditionis18.Youneedtomovea105-kgsofatoadiffer-commutative.Whichordinaryarithmeticentlocationintheroom.Ittakesaforceofoperationsarecommutative?Whicharenot?102Ntostartitmoving.Whatisthecoeffi-cientofstaticfrictionbetweenthesofaandAdditionandmultiplicationarecommu-thecarpet?tative.Subtractionanddivisionarenot.90SolutionsManualPhysics:PrinciplesandProblems
94Chapter5continuedF5.8Nf��sFN���0.58F��f�1.0�101Ns�FNFf,after��k,afterFNF��f�mg�(0.06)(1.0�101N)����102N�0.6N(105kg)(9.80m/s2)�0.0991page13022.A1.4-kgblockslidesacrossaroughsurface19.Mr.Amesisdraggingaboxfullofbookssuchthatitslowsdownwithanaccelerationfromhisofficetohiscar.Theboxandof1.25m/s2.Whatisthecoefficientofbookstogetherhaveacombinedweightofkineticfrictionbetweentheblockandthe134N.Ifthecoefficientofstaticfrictionsurface?betweenthepavementandtheboxis0.55,howhardmustMr.AmespushtheboxinFnet��kFNordertostartitmoving?ma��kmgFAmesonbox�Ffriction��a�k�g��sFN1.25m/s2��smg���29.80m/s�(0.55)(134N)�0.128�74N23.Youhelpyourmommovea41-kgbookcasetoadifferentplaceinthelivingroom.If20.Supposethatthesledinproblem17isyoupushwithaforceof65Nandtherestingonpackedsnow.Thecoefficientofbookcaseacceleratesat0.12m/s2,whatiskineticfrictionisnowonly0.12.Ifapersonthecoefficientofkineticfrictionbetweenweighing650Nsitsonthesled,whatforcethebookcaseandthecarpet?isneededtopullthesledacrossthesnowatconstantspeed?Fnet�F��kFN�F��kmg�maAtconstantspeed,appliedforceequalsF�ma���frictionforce,sok�mgFf��kFN65N�(41kg)(0.12m/s2)������(0.12)(52N�650N)(41kg)(9.80m/s2)�84N�0.1521.Supposethataparticularmachineina24.Ashuffleboarddiskisacceleratedtoaspeedfactoryhastwosteelpiecesthatmustrubof5.8m/sandreleased.Ifthecoefficientofagainsteachotherataconstantspeed.kineticfrictionbetweenthediskandtheBeforeeitherpieceofsteelhasbeentreatedconcretecourtis0.31,howfardoesthedisktoreducefriction,theforcenecessarytogetgobeforeitcomestoastop?Thecourtsarethemtoperformproperlyis5.8N.Afterthe15.8mlong.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pieceshavebeentreatedwithoil,whatwillIdentifythedirectionofthedisk’smotionbetherequiredforce?aspositive.FindtheaccelerationoftheFf,before��k,beforeFNdiskduetotheforceoffriction.Ff,beforeFnet���kFN���kmg�masoF��N��k,beforea���kgPhysics:PrinciplesandProblemsSolutionsManual91
95Chapter5continuedThenusetheequationv2�v2�(0.0m/s)�(23m/s)2fi����2a(d(2)(�0.41)(9.80m/s2)f�di)tofindthedistance.Letdi�0andsolvefordf.�66m,sohehitsthebranchbeforev2�v2hecanstop.d�f�if�2av2�v2fi���SectionReview(2)(��kg)(0.0m/s)2�(5.8m/s)25.2Friction����(2)(�0.31)(9.80m/s2)pages126–130�5.5mpage13027.FrictionInthissection,youlearnedabout25.Considertheforcepushingtheboxinstaticandkineticfriction.HowaretheseExampleProblem4.Howlongwouldittwotypesoffrictionsimilar?Whatarethetakeforthevelocityoftheboxtodoubletodifferencesbetweenstaticandkineticfriction?2.0m/s?TheyaresimilarinthattheybothactinTheinitialvelocityis1.0m/s,thefinaladirectionoppositetothemotion(orvelocityis2.0m/s,andtheaccelerationintendedmotion)andtheybothresultis2.0m/s2,sofromtwosurfacesrubbingagainsteachv�vother.Botharedependentonthenormala�f�i;lett�t�ti�0andsolvefortf.forcebetweenthesetwosurfaces.Staticfifrictionapplieswhenthereisnorelativevvt�f��imotionbetweenthetwosurfaces.Kineticf�africtionisthetypeoffrictionwhenthere����2.0m/s�1.0m/sisrelativemotion.Thecoefficientof2.0m/s2staticfrictionbetweentwosurfacesis�0.50sgreaterthanthecoefficientofkineticfric-tionbetweenthosesametwosurfaces.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.26.KeMinisdrivingalongonarainynightat23m/swhenheseesatreebranchlying28.FrictionAtaweddingreception,youacrosstheroadandslamsonthebrakesnoticeasmallboywholookslikehismasswhenthebranchis60.0minfrontofhim.isabout25kg,runningpartwayacrosstheIfthecoefficientofkineticfrictionbetweendancefloor,thenslidingonhiskneesuntilthecar’slockedtiresandtheroadis0.41,hestops.Ifthekineticcoefficientoffrictionwillthecarstopbeforehittingthebranch?betweentheboy’spantsandthefloorisThecarhasamassof2400kg.0.15,whatisthefrictionalforceactingonChoosepositivedirectionasdirectionhimasheslides?ofcar’smovement.Ffriction��kFNFnet���kFN���kmg�ma��kmga���kg�(0.15)(25kg)(9.80m/s2)Thenusetheequationv2�v2��37Nfi2a(df�di)tofindthedistance.29.VelocityDerekisplayingcardswithhisLetdi�0andsolvefordf.friends,anditishisturntodeal.Acardhas22amassof2.3g,anditslides0.35malongv�vd�f�if�2athetablebeforeitstops.Ifthecoefficient22ofkineticfrictionbetweenthecardandthev�vfi���tableis0.24,whatwastheinitialspeedof(2)(��g)kthecardasitleftDerek’shand?92SolutionsManualPhysics:PrinciplesandProblems
96Chapter5continuedIdentifythedirectionofthecard’s�kFN�Fontable�mamovementaspositiveF�maontableF���net���kFN���kmg�mak�mga���kg25N�(13kg)(0.26m/s)����v(13kg)(9.80m/s2)f�di�0so�0.17vi����2adf�Allyoucanconcludeaboutthecoeffi-����2(���kg)df�cientofstaticfrictionisthatitis2)(0.between����2(�0.24)(�9.80m��/s35m)�Fontable�1.3m/s���s�mg30.ForceThecoefficientofstaticfriction����20N(13kg)(9.80m/s2)betweena40.0-kgpicnictableandthegroundbelowitis0.43m.Whatisthe�0.16greatesthorizontalforcethatcouldbeFontableexertedonthetablewhileitremainsand�s��m�gstationary?25N����F(13kg)(9.80m/s2)f��sFN���0.20smg�(0.43)(40.0kg)(9.80m/s2)�1.7�102NPracticeProblems31.AccelerationRyanismovingtoanew5.3ForceandMotioninapartmentandputsadresserinthebackofTwoDimensionshispickuptruck.Whenthetruckacceleratespages131–135forward,whatforceacceleratesthedresser?Underwhatcircumstancescouldthedresserpage133slide?Inwhichdirection?33.Anantclimbsatasteadyspeedupthesideofitsanthill,whichisinclined30.0°fromFrictionbetweenthedresserandthethevertical.Sketchafree-bodydiagramfortruckacceleratesthedresserforward.theant.Thedresserwillslidebackwardiftheforceacceleratingitisgreaterthan�x�smg.F�yfFN32.CriticalThinkingYoupusha13-kgtableinthecafeteriawithahorizontalforceofFgy20N,butitdoesnotmove.Youthenpushitwithahorizontalforceof25N,anditFgxFgacceleratesat0.26m/s2.What,ifanything,canyouconcludeaboutthecoefficientsof60.0°Fgstaticandkineticfriction?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Fromtheslidingportionofyourexperi-mentyoucandeterminethatthecoeffi-cientofkineticfrictionbetweenthetableandthefloorisFf�Fontable�F2Physics:PrinciplesandProblemsSolutionsManual93
97Chapter5continued34.ScottandBeccaaremovingafoldingtable37.Asuitcaseisonaninclinedplane.Atwhatoutofthesunlight.Acupoflemonade,angle,relativetothevertical,willthecom-withamassof0.44kg,isonthetable.Scottponentofthesuitcase’sweightparalleltoliftshisendofthetablebeforeBeccadoes,theplanebeequaltohalftheperpendicularandasaresult,thetablemakesanangleofcomponentofitsweight?15.0°withthehorizontal.Findthecompo-Fg,parallel�Fgsin�,whentheangleisnentsofthecup’sweightthatareparallelwithrespecttothehorizontalandperpendiculartotheplaneofthetable.FFg,perpendicular�Fgcos�,whentheg,parallel�Fgsin�angleiswithrespecttothehorizontal�(0.44kg)(9.80m/s2)(sin15.0°)Fg,perpendicular�2Fg,parallel�1.1NFg,perpendicularF2���g,perpendicular�Fgcos�Fg,parallel�(0.44kg)(9.80m/s2)Fgcos����F(cos15.0°)gsin��4.2N1���tan�35.Kohana,whohasamassof50.0kg,isat�11��tan����thedentist’sofficehavingherteethcleaned,2asshowninFigure5-14.Ifthecomponent�26.6°relativetothehorizontal,orofherweightperpendiculartotheplaneof63.4°relativetotheverticaltheseatofthechairis449N,atwhatanglepage135isthechairtilted?38.ConsiderthecrateontheinclineinExampleProblem5.a.Calculatethemagnitudeoftheacceleration.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.F�a���mFgsin���■Figure5-14mFmgsin�g,perpendicular�Fgcos��mgcos����mF��cos�1����g,perpendicular�gsin�mg�(9.80m/s2)(sin30.0°)�1449N�cos�����2)2(50.0kg)(9.80m/s�4.90m/s�23.6°b.After4.00s,howfastwillthecratebemoving?36.Fernando,whohasamassof43.0kg,slidesv�va�f�i;letvdownthebanisterathisgrandparents’house.�t�ti�ti�0.fiIfthebanistermakesanangleof35.0°withSolveforvthehorizontal,whatisthenormalforcef.betweenFernandoandthebanister?vf�atfFN�mgcos��(4.90m/s2)(4.00s)�(43.0kg)(9.80m/s2)(cos35.0°)�19.6m/s�345N94SolutionsManualPhysics:PrinciplesandProblems
98Chapter5continued39.IftheskierinExampleProblem6wereonSectionReviewa31°downhillslope,whatwouldbethemagnitudeoftheacceleration?5.3ForceandMotioninSincea�g(sin���cos�),TwoDimensionsa�(9.80m/s2)(sin31°�(0.15)(cos31°))pages131–135�3.8m/s2page13542.ForcesOnewaytogetacarunstuckisto40.Stacie,whohasamassof45kg,startsdowntieoneendofastrongropetothecarandaslidethatisinclinedatanangleof45°theotherendtoatree,thenpushtheropewiththehorizontal.Ifthecoefficientofatitsmidpointatrightanglestotherope.kineticfrictionbetweenStacie’sshortsandDrawafree-bodydiagramandexplainwhytheslideis0.25,whatisheracceleration?evenasmallforceontheropecanexertaFlargeforceonthecar.Stacie’sweightparallelwithslide�Ff�maThevectorsshowninthefreebodyFStacie’sweightparallelwithslide�Ffa������diagramindicatethatevenasmallmforceperpendiculartotheropecanmgsin������kFNincreasethetensionintheropemenoughtoovercomethefrictionforce.mgsin���kmgcos�SinceF�2Tsin�(where�istheangle����mbetweentherope’soriginalpositionand�g(sin���itsdisplacedposition),kcos�)F�(9.80m/s2)[sin45°�(0.25)(cos45°)]T���2sin��5.2m/s2Forsmallervaluesof�,thetension,T,willincreasegreatly.41.Aftertheskieronthe37°hillinExampleProblem6hadbeenmovingfor5.0s,thefrictionofthesnowsuddenlyincreasedandFemadethenetforceontheskierzero.WhatFcaristhenewcoefficientoffriction?Ffrictiona�g(sin���kcos�)a�gsin��g�kcos�Ifa�0,0�gsin��g�kcos��kcos��sin�sin����k�cos�sin37°���k�cos37°�0.75Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual95
99Chapter5continued43.MassAlargescoreboardissuspendedfromtheceilingofasportsarenaby10strongcables.Sixofthecablesmakeanangleof8.0°withtheverticalwhiletheotherfourmakeanangleof10.0°.Ifthetensionineachcableis1300.0N,whatisthescoreboard’smass?Fnet,y�may�0Fnet,y�Fcablesonboard�Fg�6Fcablecos�6�4Fcablecos�4�mg�06Fcablecos�6�4Fcablecos�4m�����g6(1300.0N)(cos8.0°)�4(1300.0N)(cos10.0°)�������9.80m/s2�1.31�103kg44.AccelerationA63-kgwaterskierispulledupa14.0°inclinebyaropeparalleltotheinclinewithatensionof512N.Thecoefficientofkineticfrictionis0.27.Whatarethemagnitudeanddirectionoftheskier’sacceleration?FN�mgcos�Fropeonskier�Fg�Ff�maFropeonskier�mgsin���kmgcos��maFropeonskier�mgsin���kmgcos�a������m512N�(63kg)(9.80m/s2)(sin14.0°)�(0.27)(63kg)(9.80m/s2)(cos14.0°)����������63kg�3.2m/s2,uptheinclineCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.45.EquilibriumYouarehangingapaintingusingtwolengthsofwire.Thewireswillbreakiftheforceistoogreat.ShouldyouhangthepaintingasshowninFigures5-15aor5-15b?Explain.FgFigure5-15b;F�■Figure5-15aT�2sin�,soFTgetssmalleras�getslarger,and�islargerin5-15b.■Figure5-15b46.CriticalThinkingCanthecoefficientoffrictioneverhaveavaluesuchthataskierwouldbeabletoslideuphillataconstantvelocity?Explainwhyorwhynot.Assumetherearenootherforcesactingontheskier.No,becauseboththefrictionalforceopposingthemotionoftheskierandthecomponentofEarth’sgravityparalleltotheslopepointdownhill,notuphill.96SolutionsManualPhysics:PrinciplesandProblems
100Chapter5continued52.ExplainthemethodthatyouwouldusetoChapterAssessmentsubtracttwovectorsgraphically.(5.1)ConceptMappingReversethedirectionofthesecondpage140vectorandthenaddthem.47.Completetheconceptmapbelowbylabel-ingthecircleswithsine,cosine,ortangentto53.Explainthedifferencebetweenthesetwoindicatewhethereachfunctionispositivesymbols:AandA.(5.1)ornegativeineachquadrant.Aisthesymbolforthevectorquantity.Aisthesignedmagnitude(length)ofthevector.Quadrant54.ThePythagoreantheoremusuallyiswrittenc2�a2�b2.IfthisrelationshipisusedIIIIIIIVinvectoraddition,whatdoa,b,andcrepresent?(5.1)��������aandbrepresentthelengthsoftwovectorsthatareattherightanglestosinecosinecosinesinecosinesinetangenttangenttangentcosinetangentoneanother.crepresentsthelengthtangentofthesumofthetwovectors.MasteringConcepts55.Whenusingacoordinatesystem,howisthepage140angleordirectionofavectordetermined48.Describehowyouwouldaddtwovectorswithrespecttotheaxesofthecoordinategraphically.(5.1)system?(5.1)Makescaledrawingsofarrowsrepresent-Theangleismeasuredcounterclock-ingthevectorquantities.Placethewisefromthex-axis.arrowsforthequantitiestobeaddedtip-to-tail.Drawanarrowfromthetailofthe56.Whatisthemeaningofacoefficientoffirsttothetipofthelast.Measurethefrictionthatisgreaterthan1.0?Howlengthofthatarrowandfinditsdirection.wouldyoumeasureit?(5.2)Thefrictionalforceisgreaterthanthe49.Whichofthefollowingactionsispermissi-normalforce.Youcanpulltheobjectblewhenyougraphicallyaddonevectortoalongthesurface,measuringtheforceanother:movingthevector,rotatingtheneededtomoveitatconstantspeed.vector,orchangingthevector’slength?(5.1)Alsomeasuretheweightoftheobject.allowed:movingthevectorwithoutchanginglengthordirection57.CarsUsingthemodeloffrictiondescribedinthistextbook,wouldthefrictionbetween50.Inyourownwords,writeacleardefinitionatireandtheroadbeincreasedbyawideoftheresultantoftwoormorevectors.Doratherthananarrowtire?Explain.(5.2)notexplainhowtofindit;explainwhatitItwouldmakenodifference.Frictionrepresents.(5.1)doesnotdependuponsurfacearea.Theresultantisthevectorsumoftwoormorevectors.Itrepresentsthequan-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.58.Describeacoordinatesystemthatwouldtitythatresultsfromaddingthevectors.besuitablefordealingwithaprobleminwhichaballisthrownupintotheair.(5.3)51.HowistheresultantdisplacementaffectedOneaxisisvertical,withthepositivewhentwodisplacementvectorsareaddeddirectioneitherupordown.inadifferentorder?(5.1)Itisnotaffected.Physics:PrinciplesandProblemsSolutionsManual97
101Chapter5continued59.IfacoordinatesystemissetupsuchthatOnecomponentisparalleltothethepositivex-axispointsinadirection30°inclinedsurfaceandtheotherisabovethehorizontal,whatshouldbetheperpendiculartoit.anglebetweenthex-axisandthey-axis?Whatshouldbethedirectionofthepositive65.Forabookonaslopingtable,describey-axis?(5.3)whathappenstothecomponentoftheThetwoaxesmustbeatrightangles.weightforceparalleltothetableandtheThepositivey-axispoints30°awayforceoffrictiononthebookasyoufromtheverticalsothatitisatrightincreasetheanglethatthetablemakesanglestothex-axis.withthehorizontal.(5.3)a.Whichcomponentsofforce(s)increase60.Explainhowyouwouldsetupacoordinatewhentheangleincreases?systemformotiononahill.(5.3)AsyouincreasetheanglethetableFormotiononahill,thevertical(y)axismakeswiththehorizontal,thecom-isusuallysetupperpendicular,ornor-ponentofthebook’sweightforcemal,tothesurfaceofthehill.alongthetableincreases.b.Whichcomponentsofforce(s)decrease?61.Ifyourtextbookisinequilibrium,whatcanWhentheangleincreases,thecom-yousayabouttheforcesactingonit?(5.3)ponentoftheweightforcenormaltoThenetforceactingonthebookiszero.thetabledecreasesandthefrictionforcedecreases.62.Cananobjectthatisinequilibriumbemoving?Explain.(5.3)ApplyingConceptsYes,Newton’sfirstlawpermitsmotionpages140–141aslongastheobject’svelocityiscon-66.Avectorthatis1cmlongrepresentsadis-stant.Itcannotaccelerate.placementof5km.Howmanykilometers63.Whatisthesumofthreevectorsthat,whenarerepresentedbya3-cmvectordrawntoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.placedtiptotail,formatriangle?Ifthesethesamescale?vectorsrepresentforcesonanobject,what5km(3cm)����15kmdoesthisimplyabouttheobject?(5.3)1cmThevectorsumofforcesforminga67.MowingtheLawnIfyouarepushingaclosedtriangleiszero.Ifthesearethelawnmoweracrossthegrass,asshowninonlyforcesactingontheobject,thenetFigure5-16,canyouincreasethehorizon-forceontheobjectiszeroandthetalcomponentoftheforcethatyouexertobjectisinequilibrium.onthemowerwithoutincreasingthemag-nitudeoftheforce?Explain.64.Youareaskedtoanalyzethemotionofabookplacedonaslopingtable.(5.3)FFa.Describethebestcoordinatesystemforyanalyzingthemotion.Setupthey-axisperpendicularFtothesurfaceofthetableandthexx-axispointinguphillandparalleltothesurface.b.Howarethecomponentsoftheweightofthebookrelatedtotheangleofthetable?■Figure5-1698SolutionsManualPhysics:PrinciplesandProblems
102Chapter5continuedYes,lowerthehandletomaketheangle73.UnderwhatconditionscanthePythagoreanbetweenthehandleandthehorizontaltheorem,ratherthanthelawofcosines,besmaller.usedtofindthemagnitudeofaresultantvector?68.Avectordrawn15mmlongrepresentsaThePythagoreantheoremcanbeusedvelocityof30m/s.Howlongshouldyouonlyifthetwovectorstobeaddedaredrawavectortorepresentavelocityofatrightanglestooneanother.20m/s?15mm(20m/s)�����10mm74.Aprobleminvolvesacarmovingupahill,30m/ssoacoordinatesystemischosenwiththe69.Whatisthelargestpossibledisplacementpositivex-axisparalleltothesurfaceoftheresultingfromtwodisplacementswithmag-hill.Theproblemalsoinvolvesastonethatnitudes3mand4m?Whatisthesmallestisdroppedontothecar.Sketchtheproblempossibleresultant?Drawsketchestoandshowthecomponentsofthevelocitydemonstrateyouranswers.vectorofthestone.Thelargestis7m;thesmallestis1m.Onecomponentisinthenegativex-direction,theotherinthenegative3m4my-direction,assumingthatthepositivedirectionpointsupward,perpendicular7mtothehill.4m3mvx1mvy70.Howdoestheresultantdisplacementv+xchangeastheanglebetweentwovectorsincreasesfrom0°to180°?+yTheresultantincreases.71.AandBaretwosidesofarighttriangle,wheretan��A/B.a.Whichsideofthetriangleislongeriftan�isgreaterthan1.0?75.PullingaCartAccordingtolegend,ahorseAislonger.learnedNewton’slaws.Whenthehorsewasb.Whichsideislongeriftan�islesstoldtopullacart,itrefused,sayingthatthan1.0?ifitpulledthecartforward,accordingtoBislonger.Newton’sthirdlaw,therewouldbeanequalc.Whatdoesitmeaniftan�isequalforcebackwards;thus,therewouldbebal-to1.0?ancedforces,and,accordingtoNewton’sAandBareequalinlength.secondlaw,thecartwouldnotaccelerate.Howwouldyoureasonwiththishorse?72.TravelingbyCarAcarhasavelocityofTheequalandoppositeforcesreferredCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.50km/hinadirection60°northofeast.AtoinNewton’sthirdlawareactingoncoordinatesystemwiththepositivex-axisdifferentobjects.Thehorsewouldpullpointingeastandapositivey-axispointingonthecart,andthecartwouldpullnorthischosen.Whichcomponentoftheonthehorse.Thecartwouldhaveanvelocityvectorislarger,xory?unbalancednetforceonit(neglectingThenorthwardcomponent(y)islonger.friction)andwouldthusaccelerate.Physics:PrinciplesandProblemsSolutionsManual99
103Chapter5continued76.TennisWhenstretchingatennisnetMasteringProblemsbetweentwoposts,itisrelativelyeasyto5.1Vectorspulloneendofthenethardenoughtopages141–142removemostoftheslack,butyouneedawinchtotakethelastbitofslackoutofLevel1thenettomakethetopalmostcompletely79.CarsAcarmoves65kmdueeast,horizontal.Whyisthistrue?then45kmduewest.Whatisitstotaldisplacement?Whenstretchingthenetbetweenthetwoposts,thereisnoperpendicular65km�(�45km)�2.0�101kmcomponentupwardtobalancethe�d�2.0�101km,eastweightofthenet.Alltheforceexertedonthenetishorizontal.Stretchingthe80.Findthehorizontalandverticalcompo-nettoremovethelastbitofslacknentsofthefollowingvectors,asshowninrequiresgreatforceinordertoreduceFigure5-17.theflexibilityofthenetandtoincreasetheinternalforcesthatholdittogether.B(3.0)A(3.0)E(5.0)77.Theweightofabookonaninclinedplanecanberesolvedintotwovectorcompo-nents,onealongtheplane,andtheotherF(5.0)C(6.0)D(4.0)perpendiculartoit.a.Atwhatanglearethecomponents■Figure5-17equal?a.E45°Ex�Ecos�b.Atwhatangleistheparallelcomponent�(5.0)(cos45°)equaltozero?�3.50°Ey�Esin�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.Atwhatangleistheparallelcomponent�(5.0)(sin45°)equaltotheweight?90°�3.5b.F78.TVTowersThetransmittingtowerofaTVFx�Fcos�stationishelduprightbyguywiresthat�(5.0)(cos225°)extendfromthetopofthetowertothe��3.5ground.Theforcealongtheguywirescanberesolvedintotwoperpendicularcompo-Fy�Fsin�nents.Whichoneislarger?�(5.0)(sin225°)Thecomponentperpendiculartothe��3.5groundislargeriftheanglebetweenc.AtheguywireandhorizontalisgreaterAthan45°.x�Acos��(3.0)(cos180°)��3.0Ay�Asin��(3.0)(sin180°)�0.0100SolutionsManualPhysics:PrinciplesandProblems
104Chapter5continued81.Graphicallyfindthesumofthefollowing83.Youwalk30msouthand30meast.Findpairsofvectors,whoselengthsanddirec-themagnitudeanddirectionoftheresul-tionsareshowninFigure5-17.tantdisplacementbothgraphicallyanda.DandAalgebraically.R2�A2�B2DR���(30m)�2�(3�0m)2A�40mR(1.0)30mtan�����130mb.CandD��45°CDR�40m,45°eastofsouthR(10.0)c.CandA45�30mSR�42CA30mER(3.0)Thedifferenceintheanswersisduetod.EandFsignificantdigitsbeingconsideredinthecalculation.EF84.HikingAhiker’stripconsistsofthreeseg-R�0.0ments.PathAis8.0kmlongheading60.0°northofeast.PathBis7.0kmlonginaLevel2directiondueeast.PathCis4.0kmlong82.Graphicallyaddthefollowingsetsofheading315°counterclockwisefromeast.vectors,asshowninFigure5-17.a.Graphicallyaddthehiker’sdisplace-a.A,C,andDmentsintheorderA,B,C.ACBCDARR(7.0)b.A,B,andEb.Graphicallyaddthehiker’sdisplace-mentsintheorderC,B,A.ERR(�6.5)ACBABc.B,D,andFc.WhatcanyouconcludeabouttheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.resultingdisplacements?DYoucanaddvectorsinanyorder.BTheresultisalwaysthesame.FRPhysics:PrinciplesandProblemsSolutionsManual101
105Chapter5continued85.WhatisthenetforceactingontheringinBx�Bcos�BFigure5-18?�(128N)(cos30.0°)�y�111N500.0N400.0NBy�Bsin�B�(128N)(sin30.0°)�64N40.0°50.0°R�xx�Ax�Bx��64N�111N■Figure5-18�47NR2�A2�B2Ry�Ay�ByR���A2�B2��0N�64N��(500.0��N)2��(400.�0N)2�64N�640.3NR��R�x2��Ry2tan���A���(47N)�2��(64N)�2B�79N�1A��tan����BR�1y��tan��R���1500.0x�tan����400.0�164�tan�����51.34°fromB47Thenetforceis640.3Nat51.34°�54°86.WhatisthenetforceactingontheringinLevel3Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Figure5-19?87.AShipatSeaAshipatseaisdueintoaport500.0kmduesouthintwodays.�yHowever,aseverestormcomesinandblowsit100.0kmdueeastfromitsoriginal128Nposition.Howfaristheshipfromitsdesti-nation?Inwhatdirectionmustittravelto128N30.0°reachitsdestination?64N�x2�A2�B2RR��(100.0��km)2��(500.0km�)�2■Figure5-19�509.9kmA��128N�64NR��64N��tan�1���y�RAxx�Acos�A�1500.0�(�64N)(cos180°)�tan����100.0��64N�78.69°Ay�Asin�AR�509.9km,78.69°southofwest�(�64N)(sin180°)�0N102SolutionsManualPhysics:PrinciplesandProblems
106Chapter5continued88.SpaceExplorationAdescentvehicleland-5.2FrictioningonMarshasaverticalvelocitytowardpage142thesurfaceofMarsof5.5m/s.AtthesameLevel1time,ithasahorizontalvelocityof3.5m/s.90.Ifyouuseahorizontalforceof30.0Ntoa.Atwhatspeeddoesthevehiclemoveslidea12.0-kgwoodencrateacrossaflooralongitsdescentpath?ataconstantvelocity,whatisthecoefficientR2�A2�B2ofkineticfrictionbetweenthecrateandthefloor?R���(5.5m/s)�2��(3.5m�/s)2Ff��kFN��kmg�Fhorizontalv�R�6.5m/sF��horiz�ontalb.Atwhatanglewiththeverticalisthisk�mgpath?30.0N�����1Ry(12.0kg)(9.80m/s2)��tan��R��x�0.255�15.5�tan����3.591.A225-kgcrateispushedhorizontallywitha�58°fromhorizontal,whichis32°forceof710N.Ifthecoefficientoffrictionis0.20,calculatetheaccelerationofthecrate.fromverticalma�Fnet�Fappl�Ff89.NavigationAlfredoleavescampand,usingwhereFacompass,walks4kmE,then6kmS,f��kFN��kmg3kmE,5kmN,10kmW,8kmN,and,Thereforefinally,3kmS.Attheendofthreedays,heF�kmgappl�islost.Bydrawingadiagram,computehowa���mfarAlfredoisfromcampandwhichdirec-710N�(0.20)(225kg)(9.80m/s2)tionheshouldtaketogetbacktocamp.�����225kgTakenorthandeasttobepositive�1.2m/s2directions.North:�6km�5km�8km�3km�4km.East:4km�Level23km�10km��3km.Thehikeris92.Aforceof40.0Nacceleratesa5.0-kgblock4kmnorthand3kmwestofcamp.at6.0m/s2alongahorizontalsurface.Toreturntocamp,thehikermustgo3kmeastand4kmsouth.a.Howlargeisthefrictionalforce?R2�A2�B2ma�Fnet�Fappl�FfsoFR���(3km)�2�(4�km)2f�Fappl�ma�40.0N�(5.0kg)(6.0m/s2)�5kmR�1.0�101N�1y��tan��R��b.Whatisthecoefficientoffriction?xF�14kmf��kFN��kmg�tan����3kmFso��fk�mgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�53°1.0�101NR�5km,53°southofeast����(5.0kg)(9.80m/s2)�0.20Physics:PrinciplesandProblemsSolutionsManual103
107Chapter5continued93.MovingAppliancesYourfamilyjusthada5.3ForceandMotioninTwoDimensionsnewrefrigeratordelivered.Thedeliverymanpages142–143hasleftandyourealizethattherefrigeratorLevel1isnotquiteintherightposition,soyou95.Anobjectinequilibriumhasthreeforcesplantomoveitseveralcentimeters.Iftheexertedonit.A33.0-Nforceactsat90.0°refrigeratorhasamassof180kg,thecoeffi-fromthex-axisanda44.0-Nforceactsatcientofkineticfrictionbetweenthebottom60.0°fromthex-axis.Whatarethemagni-oftherefrigeratorandtheflooris0.13,andtudeanddirectionofthethirdforce?thestaticcoefficientoffrictionbetweenFirst,findthemagnitudeofthesumofthesesamesurfacesis0.21,howharddothesetwoforces.Theequilibrantwillyouhavetopushhorizontallytogetthehavethesamemagnitudebutoppositerefrigeratortostartmoving?direction.Fonfridge�FfrictionF1�33.0N,90.0°��sFNF2�44.0N,60.0°��smgF3�?�(0.21)(180kg)(9.80m/s2)F1x�F1cos�1�370N�(33.0N)(cos90.0°)Level3�0.0N94.StoppingataRedLightYouaredrivingF1y�F1sin�1a2500.0-kgcarataconstantspeedof14.0m/salongawet,butstraight,level�(33.0N)(sin90.0°)road.Asyouapproachanintersection,�33.0Nthetrafficlightturnsred.YouslamontheF2x�F2cos�2brakes.Thecar’swheelslock,thetiresbeginskidding,andthecarslidestoahaltina�(44.0N)(cos60.0°)distanceof25.0m.Whatisthecoefficient�22.0NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofkineticfrictionbetweenyourtiresandF2y�F2sin�2thewetroad?F�(44.0N)(sin60.0°)f��kFN�ma�38.1Nm(v2�v2)����fikmg�2�dwherevf�0F3x�F1x�F2x(Theminussignindicatestheforceis�0.0N�22.0Nactingoppositetothedirectionof�22.0Nmotion.)F3y�F1y�F2yv2��i��33.0N�38.1Nk�2dg�71.1N(14.0m/s)2����2)F3���F3x2��F3y22(25.0m)(9.80m/s�0.400��(22.0�N)�2��(71.1�N)2�74.4N104SolutionsManualPhysics:PrinciplesandProblems
108Chapter5continuedForequilibrium,thesumofthecompo-F5x�F5cos�5�(50.0N)(cos60.0°)nentsmustequalzero,so�25.0NF��tan�1�3y�180.0°F��5y�F5sin�5�(50.0N)(sin60.0°)F3x�43.3N�171.1N�tan����180.0°F22.0N6x�F1x�F2x�F3x�F4x�F5x�253°�0.0N�40.0N�0.0N�F(�40.0N)�25.0N3�74.4N,253°�25.0NLevel2F96.Fiveforcesactonanobject:(1)60.0Nat6y�F1y�F2y�F3y�F4y�F5y90.0°,(2)40.0Nat0.0°,(3)80.0Nat�60.0N�0.0N�(�80.0N)�270.0°,(4)40.0Nat180.0°,and0.0N�43.3N(5)50.0Nat60.0°.Whatarethemagni-�23.3Ntudeanddirectionofasixthforcethatwouldproduceequilibrium?F6��F�6x2��F6y2Solutionsbycomponents2�2���(25.0N)��(23.3�N)F1�60.0N,90.0°�34.2NFF2�40.0N,0.0°�16y���180.0°6�tan��FF6x3�80.0N,270.0°�123.3NF4�40.0N,180.0°�tan����180.0°25.0NF5�50.0N,60.0°�223°F6�?F6�34.2N,223°F1x�F1cos�197.AdvertisingJoewishestohangasignweighing7.50�102NsothatcableA,�(60.0N)(cos90.0°)�0.0Nattachedtothestore,makesa30.0°angle,F1y�F1sin�1�(60.0N)(sin90.0°)asshowninFigure5-20.CableBishori-�60.0Nzontalandattachedtoanadjoiningbuild-ing.WhatisthetensionincableB?F2x�F2cos�2�(40.0N)(cos0.0°)�40.0NF30.0°A2y�F2sin�2�(40.0N)(sin0.0°)�0.0NBF3x�F3cos�3�(80.0N)(cos270.0°)�0.0NF3y�F3sin�3�(80.0N)(sin270.0°)��80.0N■Figure5-20Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.F4x�F4cos�4�(40.0N)(cos180.0°)��40.0NF4y�F4sin�4�(40.0N)(sin180.0°)�0.0NPhysics:PrinciplesandProblemsSolutionsManual105
109Chapter5continuedSolutionbycomponents.ThesumofFparallel�Fgsin�thecomponentsmustequalzero,so�(215N)(sin35.0°)FAy�Fg�0�123NsoFAy�FgLevel3�7.50�102N100.EmergencyRoomYouareshadowingaFAy�FAsin60.0°nurseintheemergencyroomofalocalhospital.AnorderlywheelsinapatientFAysoF��whohasbeeninaveryseriousaccidentA�sin60.0°andhashadseverebleeding.Thenurse7.50�102Nquicklyexplainstoyouthatinacaselike���sin60.0°this,thepatient’sbedwillbetiltedwith�866NtheheaddownwardtomakesurethebrainAlso,Fgetsenoughblood.Shetellsyouthat,forB�FA�0,somostpatients,thelargestanglethatthebedFB�FAcanbetiltedwithoutthepatientbeginning�Ftoslideoffis32.0°fromthehorizontal.Acos60.0°�(866N)(cos60.0°)a.Onwhatfactororfactorsdoesthisangleoftiltingdepend?�433N,rightThecoefficientofstaticfriction98.Astreetlampweighs150N.Itissupportedbetweenthepatientandthebed’sbytwowiresthatformanangleof120.0°sheets.witheachother.Thetensionsinthewiresb.Findthecoefficientofstaticfrictionareequal.betweenatypicalpatientandthebed’sa.Whatisthetensionineachwiresup-sheets.portingthestreetlamp?Fgparalleltobed�mgsin�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Fg�2Tsin��FfFg��sFNsoT���2sin���smgcos�150N���(2)(sin30.0°)mgsin�so����1.5�102Ns�mgcos�sin�b.Iftheanglebetweenthewiressupport-��cos�ingthestreetlampisreducedto90.0°,�tan�whatisthetensionineachwire?F�tan32.0°gT���2sin��0.625150N���(2)(sin45°)�1.1�102N99.A215-Nboxisplacedonaninclinedplanethatmakesa35.0°anglewiththehorizon-tal.Findthecomponentoftheweightforceparalleltotheplane’ssurface.106SolutionsManualPhysics:PrinciplesandProblems
110Chapter5continued101.Twoblocksareconnectedbyastringoverafric-tionless,masslesspulleysuchthatoneisrestingonaninclinedplaneandtheotherishangingoverthetopedgeoftheplane,asshowninFigure5-21.Thehangingblockhasamassof16.0kg,andtheoneontheplanehasamassof8.0kg.Thecoefficientofkineticfrictionbetweentheblockandtheinclinedplaneis0.23.Theblocksarereleasedfromrest.37.0°■Figure5-21a.Whatistheaccelerationoftheblocks?F�mbotha�Fghanging�F�plane�Ffplanemhangingg�Fgplanesin���kFgplanecos�soa�������mbothmhangingg�mplanegsin���kmplanegcos��������mbothg(mhanging�mplanesin���kmplanecos�)�������mhanging�mplane(9.80m�s2)(16.0kg�(8.0kg)(sin37.0°)�(0.23)(8.0kg)(cos37.0°))���������(16.0kg�80kg)�4.0m/s2b.Whatisthetensioninthestringconnectingtheblocks?FT�Fg�Fa�mg�ma�m(g�a)�(16.0kg)(9.80m/s2�4.0m/s2)�93N102.InFigure5-22,ablockofmassMispushedwithsuchaforce,F,thatthesmallerblockofmmassmdoesnotslidedownthefrontofit.ThereisnofrictionbetweenthelargerblockFMandthesurfacebelowit,butthecoefficientofstaticfrictionbetweenthetwoblocksis�s.FindanexpressionforFintermsofM,m,�s,andg.Smallerblock:Ff,Monm��sFN,Monm�mg■Figure5-22mgF���maN,Monm��Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.sga����sPhysics:PrinciplesandProblemsSolutionsManual107
111Chapter5continuedLargerblock:b.Whatforcewillbeneededtostartthesledmoving?F–FN,monM�MaFf��sFNmgMgF�������s�ssFgg�(0.30)(4.90�102N)F��(m�M)�s�1.5�102NMixedReviewc.Whatforceisneededtokeepthesledmovingataconstantvelocity?pages143–144FLevel1f��sFN103.ThescaleinFigure5-23isbeingpulled��sFgonbythreeropes.Whatnetforcedoesthescaleread?�(0.10)(4.90�102N)�49N,kineticfrictiond.Oncemoving,whattotalforcemustbeappliedtothesledtoaccelerateitat3.0m/s2?ma�Fnet�Fappl�FfsoFappl�ma�Ff27.0°27.0°�(50.0kg)(3.0m/s2)�49N�2.0�102NLevel275.0N75.0N105.MythologySisyphuswasacharacterinGreekmythologywhowasdoomedin150.0NHadestopushabouldertothetopofaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.steepmountain.Whenhereachedthetop,■Figure5-7theboulderwouldslidebackdowntheFindthey-componentofthetwosidemountainandhewouldhavetostartallropesandthenaddthemtothemiddleoveragain.AssumethatSisyphusslidestherope.boulderupthemountainwithoutbeingFy�Fcos�abletorollit,eventhoughinmostver-sionsofthemyth,herolledit.�(75.0N)(cos27.0°)a.Ifthecoefficientofkineticfriction�66.8Nbetweentheboulderandthemountain-Fy,total�Fy,left�Fy,middle�Fy,rightsideis0.40,themassoftheboulderis�66.8N�150.0N�66.8N20.0kg,andtheslopeofthemountainisaconstant30.0°,whatistheforce�283.6NthatSisyphusmustexertonthebouldertomoveitupthemountainatacon-104.SleddingAsledwithamassof50.0kgisstantvelocity?pulledalongflat,snow-coveredground.Thestaticfrictioncoefficientis0.30,andFSonrock�Fg�toslope�Ffthekineticfrictioncoefficientis0.10.�FSonrock�mgsin��a.Whatdoesthesledweigh?�F2)kmgcos��ma�0g�mg�(50.0kg)(9.80m/s�4.90�102NFSonrock�mgsin���kmgcos�108SolutionsManualPhysics:PrinciplesandProblems
112Chapter5continued�mg(sin���kcos�)�(20.0kg)(9.80m/s2)(sin30.0°�(0.40)(cos30.0°))�166Nb.IfSisyphuspushestheboulderatavelocityof0.25m/sandittakeshim8.0htoreachthetopofthemountain,whatisthemythicalmountain’sverticalheight?h�dsin��vtsin��(0.25m/s)(8.0h)(3600s/h)(sin30.0°)�3.6�103m�3.6kmLevel3106.LandscapingAtreeisbeingtransportedonaflatbedtrailerbyalandscaper,asshowninFigure5-24.Ifthebaseofthetreeslidesonthetreewillthetrailer,falloverandbedamaged.Ifthecoefficientofstaticfrictionbetweenthetreeandthetraileris0.50,whatistheminimumstoppingdistanceofthetruck,travelingat55km/h,ifitistoaccelerateuniformlyandnothavethetreeslideforwardandfallonthetrailer?■Figure5-24Ftruck��Ff���sFN���smg�ma��a�s�mg����msg��(0.50)(9.80m/s2)��4.9m/s2v2�v2�2a�dwithvfif�0,v2so�d��i��2a1000m1h2��(55km/h)���������1km3600s����(2)(�4.9m�s2)�24mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual109
113Chapter5continuedThinkingCriticallypage144107.UseModelsUsingtheExampleProblemsinthischapterasmodels,writeanexampleproblemtosolvethefollowingproblem.Includethefollowingsections:AnalyzeandSketchtheProblem,SolvefortheUnknown(withacompletestrategy),andEvaluatetheAnswer.Adriverofa975-kgcartraveling25m/sputsonthebrakes.Whatistheshortestdistanceitwilltakeforthecartostop?Assumethattheroadisconcrete,theforceoffrictionoftheroadonthetiresisconstant,andthetiresdonotslip.didf25m/sFN+xvFfFnetaFgAnalyzeandSketchtheProblem•Chooseacoordinatesystemwithapositiveaxisinthedirectionofmotion.•Drawamotiondiagram.•Labelvanda.•Drawthefree-bodydiagram.Known:Unknown:di�0df�?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.vi�25m/svf�0m�975kg�s�0.80SolvefortheUnknownSolveNewton’ssecondlawfora.�Fnet�ma�Ff�maSubstitute�Ff��Fnet��FN�maSubstituteFf��FN��mg�maSubstituteFN�mga���gUsetheexpressionforaccelerationtosolvefordistance.v2�v2�2a(dfif�di)v2�v2d�f�if�di�2av2�v2�d�f�iSubstitutea���gi�(2)(��g)110SolutionsManualPhysics:PrinciplesandProblems
114Chapter5continued(0.0m/s)2�(25m/s)2Substituted�0.0m����i�0.0m,vf�0.0m/s,(2)(�0.65)(9.80m/s)2v2i�25m/s,��0.65,g�9.80m/s�49m108.AnalyzeandConcludeMargaretMary,Doug,andKakoareatalocalamusementparkandseeanattractioncalledtheGiantSlide,whichissimplyaverylongandhighinclinedplane.Visitorsattheamusementparkclimbalongflightofstepstothetopofthe27°inclinedplaneandaregivencanvassacks.Theysitonthesacksandslidedownthe70-m-longplane.Atthetimewhenthethreefriendswalkpasttheslide,a135-kgmananda20-kgboyareeachatthetoppreparingtoslidedown.“Iwonderhowmuchlesstimeitwilltakethemantoslidedownthanitwilltaketheboy,”saysMargaretMary.“Ithinktheboywilltakelesstime,”saysDoug.“You’rebothwrong,”saysKako.“Theywillreachthebottomatthesametime.”a.Performtheappropriateanalysistodeterminewhoiscorrect.Fnet�Fg�Ff�Fgsin���kFN�mgsin���kmgcos��maa�g(sin���kcos�),sotheaccelerationisindependentofthemass.Theywilltie,soKakoiscorrect.b.Ifthemanandtheboydonottakethesameamountoftimetoreachtheoftheslide,calculatehowmanysecondsofdifferencetherewillbebetweenthetwotimes.Theywillreachthebottomatthesametime.WritinginPhysicspage144109.Investigatesomeofthetechniquesusedinindustrytoreducethefrictionbetweenvariouspartsofmachines.Describetwoorthreeofthesetechniquesandexplainthephysicsofhowtheywork.Answerswillvaryandmayincludelubricantsandreductionofthenormalforcetoreducetheforceoffriction.110.OlympicsInrecentyears,manyOlympicathletes,suchassprinters,swimmers,skiers,andspeedskaters,haveusedmodifiedequipmenttoreducetheeffectsoffrictionandairorwaterdrag.Researchapieceofequipmentusedbyoneofthesetypesofathletesandthewayithaschangedovertheyears.Explainhowphysicshasimpactedthesechanges.Answerswillvary.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual111
115Chapter5continuedCumulativeReviewChallengeProblempage144page132111.AddorsubtractasindicatedandstatetheFindtheequilibrantforthefollowingforces.answerwiththecorrectnumberofsignifi-Fcantdigits.(Chapter1)1�61.0Nat17.0°northofeastF2�38.0Nat64.0°northofeasta.85.26g�4.7gF3�54.0Nat8.0°westofnorth90.0gF4�93.0Nat53.0°westofnorthb.1.07km�0.608kmF5�65.0Nat21.0°southofwestF1.68km6�102.0Nat15.0°westofsouthFc.186.4kg�57.83kg7�26.0NsouthF8�77.0Nat22.0°eastofsouth128.6kgF9�51.0Nat33.0°eastofsouthd.60.08s�12.2sF10�82.0Nat5.0°southofeast47.9s�y112.Yourideyourbikefor1.5hatanaverage43velocityof10km/h,thenfor30minat215km/h.Whatisyouraveragevelocity?1(Chapter3)�xAveragevelocityisthetotaldisplace-10mentdividedbythetotaltime.579d�dv��f�i�t�tfi8v���1t1�v2t2�dit1�t2�ti6di�ti�0,soCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.F1x�(61.0N)(cos17.0°)�58.3Nvv����1t1�v2t2t1�t2F1y�(61.0N)(sin17.0°)�17.8N(10km�h)(1.5h)�(15km�h)(0.5h)������F1.5h�0.5h2x�(38.0N)(cos64.0°)�16.7N�10km/hF2y�(38.0N)(sin64.0°)�34.2N113.A45-NforceisexertedintheupwardF3x��(54.0N)(sin8.0°)��7.52Ndirectionona2.0-kgbriefcase.WhatistheFaccelerationofthebriefcase?(Chapter4)3y�(54.0N)(cos8.0°)�53.5NFnet�Fapplied�Fg�Fapplied�mgF4x��(93.0N)(sin53.0°)��74.3N�maF4y�(93.0N)(cos53.0°)�56.0NF��applied�mgsoa�mF5x��(65.0N)(cos21.0°)��60.7N45N�(2.0kg)(9.80m�s2)�����F5y��(65.0N)(sin21.0°)��23.3N2.0kg�13m/s2F6x��(102N)(sin15.0°)��26.4NF6y��(102N)(cos15.0°)��98.5N112SolutionsManualPhysics:PrinciplesandProblems
116Chapter5continued10F7x�0.0NFFy��iyi�1F7y��26.0N��107.65NF8x�(77.0N)(sin22.0°)�28.8NF��2��(F2R�(Fx)y)F8y��(77.0N)(cos22.0°)��71.4N��(44.38��N)2��(�107.65N�)�2F9x�(51.0N)(sin33.0°)�27.8N�116NF9y��(51.0N)(cos33.0°)��42.8NF�1y��R�tan��FxF10x�(82.0N)(cos5.0°)�81.7N�1�107.65NF�tan����10y��(82.0N)(sin5.0°)��7.15N44.38N��67.6°10Fx��FixFequilibrant�116Nat112.4°i�1�44.38N�116Nat22.4°WofNCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual113
117
118CHAPTER6MotioninTwoDimensions2.LucyandherfriendareworkingatanPracticeProblemsassemblyplantmakingwoodentoy6.1ProjectileMotiongiraffes.Attheendoftheline,thegiraffespages147–152gohorizontallyofftheedgeoftheconveyorbeltandfallintoaboxbelow.Iftheboxispage1500.6mbelowtheleveloftheconveyorbelt1.Astoneisthrownhorizontallyataspeedand0.4mawayfromit,whatmustbetheof5.0m/sfromthetopofacliffthatishorizontalvelocityofgiraffesastheyleave78.4mhigh.theconveyorbelt?a.Howlongdoesittakethestonetoreachthebottomofthecliff?�2yx�v��xt�vx��g12Sincev��gty�0,y�vyt��2xsovx�12�2ybecomesy����gt����2g2y0.4mort���������g(�2)(�0.6m)���(2)(�78.4m)��9.80�m/s2�������9.80m/s2��1m/s�4.00s3.Youarevisitingafriendfromelementaryb.Howfarfromthebaseofthecliffdoesschoolwhonowlivesinasmalltown.Onethestonehittheground?localamusementistheice-creamparlor,x�vxtwhereStan,theshort-ordercook,slideshis�(5.0m/s)(4.00s)completedice-creamsundaesdownthecounterataconstantspeedof2.0m/sto�2.0�101mtheservers.(Thecounteriskeptverywellc.Whatarethehorizontalandverticalpolishedforthispurpose.)Iftheserverscomponentsofthestone’svelocityjustcatchthesundaes7.0cmfromtheedgeofbeforeithitstheground?thecounter,howfardotheyfallfromthevedgeofthecountertothepointatwhichx�5.0m/s.Thisisthesameastheinitialhorizontalspeedbecausethetheserverscatchthem?accelerationofgravityinfluencesx�vxt;onlytheverticalmotion.Forthexverticalcomponent,usev�vt��v�i�gtxwithv�vyandvi,theinitialvertical12componentofvelocity,zero.y���gt2Att�4.00s1x2���g����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2vxvy�gt�(9.80m/s2)(4.0s)���1(9.80m/s2)��0.07�0m�222.0m/s�39.2m/s�0.0060mor0.60cmPhysics:PrinciplesandProblemsSolutionsManual115
119Chapter6continuedpage1524.AplayerkicksafootballfromgroundTrajectory25levelwithaninitialvelocityof27.0m/s,60.0°30.0°abovethehorizontal,asshowninFigure6-4.Findeachofthe(m)yfollowing.Assumethatair30.0°resistanceisnegligible.0x(m)60a.theball’shangtime■Figure6-4vy�visin�Whenitlands,y�v�12�0.yt�2gtTherefore,2v2�ytt��g2vyt���g2vin��is��g(2)(27.0m/s)(sin30.0°)����9.80m/s2�2.76sb.theball’smaximumheightMaximumheightoccursathalfthe“hangtime,”or1.38s.Thus,12y�v��gtyt�2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12�v�isin�t�2gt�(27.0m/s)(sin30.0°)(1.38s)��1(�9.80m/s2)(1.38s)22�9.30mc.theball’srangeDistance:vx�vicos�x�vxt�(vicos�)(t)�(27.0m/s)(cos30.0°)(2.76s)�64.5m5.Theplayerinproblem4thenkickstheballwiththesamespeed,butat60.0°fromthehorizontal.Whatistheball’shangtime,range,andmaximumheight?FollowingthemethodofPracticeProblem4,Hangtime:2vin�t�is��g(2)(27.0m/s)(sin60.0°)����29.80m/s�4.77s116SolutionsManualPhysics:PrinciplesandProblems
120Chapter6continuedDistance:x�vicos�t�(27.0m/s)(cos60.0°)(4.77s)�64.4mMaximumheight:1att���(4.77s)�2.38s212y�v��gtisin�t�212)(2.38s)2�(27.0m/s)(sin60.0°)(2.38s)���(�9.80m/s2�27.9m6.Arockisthrownfroma50.0-m-highcliffwithaninitialvelocityof7.0m/satanangleof53.0°abovethehorizontal.Findthevelocityvectorforwhenithitsthegroundbelow.vx�vicos�vy�visin��gt2y�v�isin��g��g�visin���2�ygv��v�x2��vy2��(�vicos��)2��(visin����2�yg)22��((7.0m/s�)cos53��.0°)2��(7.0m/s)�(sin53.0�°)���(2��)(50�.0m)(��9.80m�/s2)��37m/sv�1y��tan���vx�tan�1�����visin�i��2�ygvicos�i�1(7.0m/s)(sin53.0°)��(2)(50�.0m)(�9.80m�/s�2)�tan�������(7.0m/s)(cos53.0°)�83°fromhorizontalSectionReview6.1ProjectileMotionCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pages147–152page1527.ProjectileMotionTwobaseballsarepitchedhorizontallyfromthesameheight,butatdifferentspeeds.Thefasterballcrosseshomeplatewithinthestrikezone,buttheslowerballisbelowthebatter’sknees.Whydoesthefasterballnotfallasfarastheslowerone?Physics:PrinciplesandProblemsSolutionsManual117
121Chapter6continuedThefasterballisintheairashortertime,andthusgainsasmallerverticalvelocity.8.Free-BodyDiagramAnicecubeslideswithoutfrictionacrossatableataconstantvelocity.Itslidesoffthetableandlandsonthefloor.Drawfree-bodyandmotiondiagramsoftheicecubeattwopointsonthetableandattwopointsintheair.Free-BodyDiagramsMotionDiagramsOnthetableIntheairOnthetableIntheairFFa�0NNaFgFgFgFg9.ProjectileMotionAsoftballistossedintotheairatanangleof50.0°withtheverticalataninitialvelocityof11.0m/s.Whatisitsmaximumheight?v2�v2�2a(dfiyf�di);a��g,di�0Atmaximumheightvf�0,sov2iyd��f�2g(vos�)2�ic��2g((11.0m/s)(cos50.0°))2����(2)(9.80m/s2)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�2.55m10.ProjectileMotionAtennisballisthrownoutawindow28mabovethegroundataninitialvelocityof15.0m/sand20.0°belowthehorizontal.Howfardoestheballmovehorizontallybeforeithitstheground?x�v0xt,butneedtofindtFirst,determinevyf:v2�v2�2gyyfyivyf��v�yi2��2gy��(�visin��)2��2gy��((15.0��m/s)(sin20��.0°))2�(2)(9.80m��/s2)(28�m)�24.0m/sNowusevyf�vyi�gttofindt.vvyf�yit���gvvyf�isin����g118SolutionsManualPhysics:PrinciplesandProblems
122Chapter6continued2.40m/s�(15.0m/s)(sin20.0°)�����9.80m/s2�1.92sx�vxit�(vicos�)(t)�(15.0m/s)(cos20.0°)(1.92s)�27.1m11.CriticalThinkingSupposethatanobjectisthrownwiththesameinitialvelocityanddirectiononEarthandontheMoon,wheregisone-sixththatonEarth.Howwillthefollowingquantitieschange?a.vxwillnotchangeb.theobject’stimeofflight�2vywillbelarger;t��gc.ymaxwillbelargerd.RwillbelargerPracticeProblems6.2CircularMotionpages153–156page15612.Arunnermovingataspeedof8.8m/sroundsabendwitharadiusof25m.Whatisthecentripetalaccelerationoftherunner,andwhatagentexertsforceontherunner?v2(8.8m/s)22,thefrictionalforceofthetrackactingona������3.1m/sc�r25mtherunner’sshoesexertstheforceontherunner.13.Acarracingonaflattracktravelsat22m/saroundacurvewitha56-mradius.Findthecar’scentripetalacceleration.Whatminimumcoefficientofstaticfrictionbetweenthetiresandroadisnecessaryforthecartoroundthecurvewithoutslipping?v2(22m/s)22a������8.6m/sc�r56mRecallFf��FN.ThefrictionforcemustsupplythecentripetalforcesoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Ff�mac.ThenormalforceisFN��mg.ThecoefficientoffrictionmustbeatleastFfmacac8.6m/s2��������������0.88FNmgg9.80m/s2Physics:PrinciplesandProblemsSolutionsManual119
123Chapter6continued14.Anairplanetravelingat201m/smakesab.Whatisthedirectionofthenetforceturn.Whatisthesmallestradiusofthethatisactingonyou?circularpath(inkm)thatthepilotcanThenetforceactingonyourbodyismakeandkeepthecentripetalaccelerationtotherightunder5.0m/s2?c.Whatexertsthisforce?v2v2(201m/s)2Theforceisexertedbythecar’sa��,sor�������8.1kmc�rac5.0m/s2seat.15.A45-kgmerry-go-roundworkerstandson18.CentripetalForceIfa40.0-gstoneistheride’splatform6.3mfromthecenter.whirledhorizontallyontheendofaIfherspeedasshegoesaroundthecircle0.60-mstringataspeedof2.2m/s,whatisis4.1m/s,whatistheforceoffrictionthetensioninthestring?necessarytokeepherfromfallingofftheFT�macplatform?mv2mv2(45kg)(4.1m/s)2��r�F�������120Nf�Fc�r6.3m(0.0400kg)(22m/s)2����0.60mSectionReview�0.32N6.2CircularMotion19.CentripetalAccelerationAnewspaperpages153–156articlestatesthatwhenturningacorner,page156adrivermustbecarefultobalancethe16.UniformCircularMotionWhatisthecentripetalandcentrifugalforcestokeepdirectionoftheforcethatactsonthefromskidding.Writealettertotheeditorclothesinthespincycleofawashingthatcritiquesthisarticle.machine?Whatexertstheforce?ThelettershouldstatethatthereisanTheforceistowardthecenterofthetub.accelerationbecausethedirectionofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thewallsofthetubexerttheforceonthevelocityischanging;therefore,theclothes.Ofcourse,thewholepointistheremustbeanetforceinthedirec-thatsomeofthewaterintheclothestionofthecenterofthecircle.Theroadgoesoutthroughholesinthewallofthesuppliesthatforceandthefrictiontubratherthanmovingtowardthecenter.betweentheroadandthetiresallowstheforcetobeexertedonthetires.The17.Free-BodyDiagramYouaresittinginthecar’sseatexertstheforceonthedriverbackseatofacargoingaroundacurvetothethataccelerateshimorhertowardtheright.Sketchmotionandfree-bodydiagramscenterofthecircle.Thenotealsotoanswerthefollowingquestions.shouldmakeitclearthatcentrifugalforceisnotarealforce.20.CentripetalForceAbowlingballhasaamassof7.3kg.IfyoumoveitaroundaFcirclewitharadiusof0.75mataspeednetvof2.5m/s,whatforcewouldyouhavetoexertonit?a.WhatisthedirectionofyourFacceleration?net�macYourbodyisacceleratedtothemv2��right.r120SolutionsManualPhysics:PrinciplesandProblems
124Chapter6continued(7.3kg)(2.5m/s)2so,vw/g�vb/g�vb/w����0.75m�0.5m/s�2.5m/s�61N�2.0m/s;againsttheboat21.CriticalThinkingBecauseofEarth’sdaily25.Anairplanefliesduenorthat150km/hrelativerotation,youalwaysmovewithuniformtotheair.Thereisawindblowingat75km/hcircularmotion.Whatistheagentthattotheeastrelativetotheground.Whatisthesuppliestheforcethatacceleratesyou?plane’sspeedrelativetotheground?Howdoesthismotionaffectyourapparentweight?v��v�p2��vw2Earth’sgravitysuppliestheforcethatacceleratesyouincircularmotion.Your��(150k��m/h)2��(75�km/h)�2uniformcircularmotiondecreasesyour�1.7�102km/happarentweight.SectionReviewPracticeProblems6.3RelativeVelocity6.3RelativeVelocitypages157–159pages157–159page159page15926.RelativeVelocityAfishingboatwitha22.Youareridinginabusmovingslowlymaximumspeedof3m/srelativetothethroughheavytrafficat2.0m/s.Youhurrywaterisinariverthatisflowingat2m/s.tothefrontofthebusat4.0m/srelativetoWhatisthemaximumspeedtheboatcanthebus.Whatisyourspeedrelativetotheobtainrelativetotheshore?Theminimumstreet?speed?Givethedirectionoftheboat,rela-vy/g�vb/g�vy/btivetotheriver’scurrent,forthemaximumspeedandtheminimumspeedrelativeto�2.0m/s�4.0m/stheshore.�6.0m/srelativetostreetThemaximumspeedrelativetotheshoreiswhentheboatmovesatmaxi-23.Rafiispullingatoywagonthroughthemumspeedinthesamedirectionasneighborhoodataspeedof0.75m/s.theriver’sflow:Acaterpillarinthewagoniscrawlingtowardtherearofthewagonatarateofvb/s�vb/w�vw/s2.0cm/s.Whatisthecaterpillar’svelocity�3m/s�2m/srelativetotheground?�5m/svc/g�vw/g�vc/wTheminimumspeedrelativetothe�0.75m/s�0.02m/sshoreiswhentheboatmovesintheoppositedirectionoftheriver’sflow�0.73m/swiththesamespeedastheriver:24.Aboatisroweddirectlyupriverataspeedvb/s�vb/w�vw/sof2.5m/srelativetothewater.ViewersonCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�3m/s�(�2m/s)theshoreseethattheboatismovingatonly0.5m/srelativetotheshore.Whatis�1m/sthespeedoftheriver?Isitmovingwithoragainsttheboat?vb/g�vb/w�vw/g;Physics:PrinciplesandProblemsSolutionsManual121
125Chapter6continued27.RelativeVelocityofaBoatApowerboatheadsduenorthwestat13m/srelativetothewateracrossariverthatflowsduenorthat5.0m/s.Whatisthevelocity(bothmagnitudeanddirection)ofthemotorboatrelativetotheshore?vR��v�RN2��vRW2���(vbN��vrN)2�(vbW��vrW)�2��(�vbsin���v�r)2�(v�bcos��)2��((13m�/s)(sin��45°)��5.0m�/s)2��((13m/s)(co�s45°)�)�2�17m/sv�1RW��tan����vRNv�1bcos��tan����vbsin��vr�1����(13m/s)(cos45°)�tan��(3m/s)(sin45°)�5.0m/s�33°vR�17m/s,33°westofnorth28.RelativeVelocityAnairplanefliesduesouthat175km/hrelativetotheair.Thereisawindblowingat85km/htotheeastrelativetotheground.Whataretheplane’sspeedanddirectionrelativetotheground?vR��(175k��m/h)2��(85�km/h)�2�190km/h�1175km/h��tan�����64°85km/hvR�190km/h,64°southofeastCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.29.APlane’sRelativeVelocityAnairplanefliesduenorthat235km/hrelativetotheair.Thereisawindblowingat65km/htothenortheastrelativetotheground.Whataretheplane’sspeedanddirectionrelativetotheground?vR���vRE2��vRN2���(vpE��vaE)2��(vp�N�vw�N)2��(�vwco�s�)2��(vp��vwsin��)2���((65k�m/h)(c�os45�°))2��(235�km/h�(65�km/h�)(sin4�5°))2�280km/hv�1RN��tan����vREv�1p�vasin��tan����vacos��1235km/h�(65km/h)(sin45°)�tan������(65km/h)(cos45°)�72°northofeast280km/h,72°northofeast122SolutionsManualPhysics:PrinciplesandProblems
126Chapter6continued30.RelativeVelocityAnairplanehasaspeedof285km/hrelativetotheair.Thereisawindblowingat95km/hat30.0°northofeastrelativetoEarth.Inwhichdirectionshouldtheplaneheadtolandatanairportduenorthofitspresentlocation?Whatistheplane’sspeedrelativetotheground?Totravelnorth,theeastcomponentsmustbeequalandopposite.vpWcos��p�v,sopRv�1pW�p�cos���vpRv�1wEcos�w�cos����vpR�1(95km/h)(cos30.0°)�cos�����285km/h�73°northofwestvpR�vpN�vwN�vpsin�p�vwsin�w�(285km/h)(sin107°)�(95km/h)(sin30.0°)�320km/h31.CriticalThinkingYouarepilotingaboatacrossafast-movingriver.Youwanttoreachapierdirectlyoppositeyourstartingpoint.Describehowyouwouldnavigatetheboatintermsofthecomponentsofyourvelocityrelativetothewater.Youshouldchoosethecomponentofyourvelocityalongthedirectionoftherivertobeequalandoppositetothevelocityoftheriver.ChapterAssessmentConceptMappingpage16432.Usethefollowingtermstocompletetheconceptmapbelow:constantspeed,horizontalpartofprojectilemotion,constantacceleration,relative-velocitymotion,uniformcircularmotion.CategoriesofMotionconstantconstantconstantaccelerationvelocityspeedCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.verticalparthorizontalrelative-velocityuniformcircularofprojectilepartofprojectilemotionmotionmotionmotionPhysics:PrinciplesandProblemsSolutionsManual123
127Chapter6continuedMasteringConceptspage16433.ConsiderthetrajectoryofthecannonballshowninFigure6-11.(6.1)BACDE■Figure6-11Upispositive,downisnegative.a.Whereisthemagnitudeofthevertical-velocitycomponentlargest?ThegreatestverticalvelocityoccursatpointA.b.Whereisthemagnitudeofthehorizontal-velocitycomponentlargest?Neglectingairresistance,thehorizontalvelocityatallpointsisthesame.Horizontalvelocityisconstantandindependentofverticalvelocity.c.Whereisthevertical-velocitysmallest?TheleastverticalvelocityoccursatpointE.d.Whereisthemagnitudeoftheaccelerationsmallest?Themagnitudeoftheaccelerationisthesameeverywhere.34.Astudentisplayingwitharadio-controlledracecaronthebalconyofasixth-floorapartment.Anaccidentalturnsendsthecarthroughtherailingandovertheedgeofthebalcony.DoesthetimeittakesthecartofalldependupontheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.speedithadwhenitleftthebalcony?(6.1)No,thehorizontalcomponentofmotiondoesnotaffecttheverticalcomponent.35.Anairplanepilotflyingatconstantvelocityandaltitudedropsaheavycrate.Ignoringairresistance,wherewilltheplaneberelativetothecratewhenthecratehitstheground?Drawthepathofthecrateasseenbyanobserverontheground.(6.1)Theplanewillbedirectlyoverthecratewhenthecratehitstheground.Bothhavethesamehorizontalvelocity.Thecratewilllooklikeitismovinghorizontallywhilefallingverticallytoanobserverontheground.36.Canyougoaroundacurvewiththefollowingaccelerations?Explain.a.zeroaccelerationNo,goingaroundacurvecausesachangeindirectionofvelocity.Thus,theaccelerationcannotbezero.b.constantacceleration(6.2)No,themagnitudeoftheaccelerationmaybeconstant,butthedirectionoftheaccelerationchanges.124SolutionsManualPhysics:PrinciplesandProblems
128Chapter6continued37.Toobtainuniformcircularmotion,how41.BaseballAbatterhitsapop-upstraightmustthenetforcedependonthespeedupoverhomeplateataninitialvelocityofthemovingobject?(6.2)of20m/s.TheballiscaughtbythecatcherCircularmotionresultswhentheatthesameheightthatitwashit.Atwhatdirectionoftheforceisconstantlyvelocitydoestheballlandinthecatcher’sperpendiculartotheinstantaneousmitt?Neglectairresistance.velocityoftheobject.�20m/s,wherethenegativesignindicatesdown38.Ifyouwhirlayo-yoaboutyourheadinahorizontalcircle,inwhatdirectionmusta42.FastballInbaseball,afastballtakesaboutforceactontheyo-yo?Whatexertsthe�1�storeachtheplate.Assumingthatsucha2force?(6.2)pitchisthrownhorizontally,comparetheTheforceisalongthestringtowardthe1distancetheballfallsinthefirst��swithcenterofthecirclethattheyo-yofol-4lows.Thestringexertstheforce.1thedistanceitfallsinthesecond��s.4Becauseoftheaccelerationduetograv-39.Whyisitthatacartravelingintheoppositeity,thebaseballfallsagreaterdistancedirectionasthecarinwhichyouareriding1onthefreewayoftenlookslikeitismovingduringthesecond��sthanduringthe41fasterthanthespeedlimit?(6.3)first��s.4Themagnitudeoftherelativevelocity43.Youthrowarockhorizontally.Inasecondofthatcartoyourcarcanbefoundbyhorizontalthrow,youthrowtherockharderaddingthemagnitudesofthetwocars’andgiveitevenmorespeed.velocitiestogether.Sinceeachcarprobablyismovingatclosetothea.Howwillthetimeittakestherocktospeedlimit,theresultingrelativeveloci-hitthegroundbeaffected?Ignoreairtywillbelargerthanthepostedspeedresistance.limit.Thetimedoesnotchange—thetimeittakestohitthegrounddependsonlyApplyingConceptsonverticalvelocitiesandaccelera-pages164–165tion.40.ProjectileMotionAnalyzehowhorizontalb.Howwilltheincreasedspeedaffectthemotioncanbeuniformwhileverticaldistancefromwheretherockleftyourmotionisaccelerated.Howwillprojectilehandtowheretherockhitstheground?motionbeaffectedwhendragduetoairAhigherhorizontalspeedproducesresistanceistakenintoconsideration?alongerhorizontaldistance.Thehorizontalmotionisuniformbecausetherearenoforcesactingin44.FieldBiologyAzoologiststandingonathatdirection(ignoringfriction).Thecliffaimsatranquilizergunatamonkeyverticalmotionisacceleratedduetohangingfromadistanttreebranch.Thetheforceofgravity.Theprojectilebarrelofthegunishorizontal.Justasthemotionequationsinthisbookdonotzoologistpullsthetrigger,themonkeyletsholdwhenfrictionistakenintogoandbeginstofall.WillthedarthittheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.account.Projectilemotioninbothmonkey?Ignoreairresistance.directionswillbeimpactedwhenYes,infact,themonkeywouldbesafeifdragduetoairresistanceistakenitdidnotletgoofthebranch.Theverti-intoconsideration.Therewillbeacalaccelerationofthedartisthesamefrictionforceopposingthemotion.asthatofthemonkey.Therefore,thedartisatthesameverticalheightwhenPhysics:PrinciplesandProblemsSolutionsManual125
129Chapter6continueditreachesthemonkey.45.FootballAquarterbackthrowsafootballat24m/sata45°angle.Ifittakestheball3.0storeachthetopofitspathandtheballiscaughtatthesameheightatwhichitisthrown,howlongisitintheair?Ignoreairresistance.6.0s:3.0supand3.0sdown46.TrackandFieldYouareworkingonimprovingyourperformanceinthelongjumpandbelievethattheinformationinthischaptercanhelp.Doestheheightthatyoureachmakeanydifferencetoyourjump?Whatinfluencesthelengthofyourjump?Bothspeedandangleoflaunchmatter,soheightdoesmakeadifference.Maximumrangeisachievedwhentheresultantvelocityhasequalverticalandhorizontalcomponents—inotherwords,alaunchangleof45°.Forthisreason,heightandspeedaffecttherange.47.Imaginethatyouaresittinginacartossingaballstraightupintotheair.a.Ifthecarismovingataconstantvelocity,willtheballlandinfrontof,behind,orCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.inyourhand?Theballwilllandinyourhandbecauseyou,theball,andthecarallaremovingforwardwiththesamespeed.b.Ifthecarroundsacurveataconstantspeed,wherewilltheballland?Theballwilllandbesideyou,towardtheoutsideofthecurve.Atopviewwouldshowtheballmovingstraightwhileyouandthecarmovedoutfromundertheball.48.Youswingoneyo-yoaroundyourheadinahorizontalcircle.Thenyouswinganotheryo-yowithtwicethemassofthefirstone,butyoudon’tchangethelengthofthestringortheperiod.Howdothetensionsinthestringsdiffer?ThetensioninthestringisdoubledsinceFT�mac.126SolutionsManualPhysics:PrinciplesandProblems
130Chapter6continued49.CarRacingThecurvesonaracetrackareshouldyoulookforthekeys?bankedtomakeiteasierforcarstogo12y�v�aroundthecurvesathighspeeds.Drawayt�2gtfree-bodydiagramofacaronabankedSinceinitialverticalvelocityiszero,curve.Fromthemotiondiagram,findthe�2y(�2)(�64m)directionoftheacceleration.t����g����9.80��m/s2�FrontViewTopView�3.6sv2v1x�vFNxt�(8.0m/s)(3.6)�28.8mv1�29m�vv2a52.ThetoycarinFigure6-12runsofftheedgeFgofatablethatis1.225-mhigh.Thecarlands0.400mfromthebaseofthetable.vTheaccelerationisdirectedtowardthecenterofthetrack.a.Whatexertstheforceinthedirectionoftheacceleration?Thecomponentofthenormalforceactingtowardthecenterofthecurve,anddependingonthecar’s1.225mspeed,thecomponentofthefrictionforceactingtowardthecenter,bothcontributetothenetforceinthedirectionofacceleration.b.Canyouhavesuchaforcewithout0.400mfriction?■Figure6-12Yes,thecentripetalaccelerationneeda.Howlongdidittakethecartofall?onlybeduetothenormalforce.12y�v�y0t�2gt50.DrivingontheHighwayExplainwhyitisSinceinitialverticalvelocityiszero,thatwhenyoupassacargoinginthesamedirectionasyouonthefreeway,ittakesa�2y(�2)(�1.225m)t�����longertimethanwhenyoupassacargoing��g���9.80m/s2intheoppositedirection.�0.500sTherelativespeedoftwocarsgoinginb.Howfastwasthecargoingonthetable?thesamedirectionislessthantherela-x0.400mtivespeedoftwocarsgoinginthev����0.800m/sx��t0.500soppositedirection.Passingwiththelesserrelativespeedwilltakelonger.53.Adartplayerthrowsadarthorizontallyat12.4m/s.Thedarthitstheboard0.32mMasteringProblemsbelowtheheightfromwhichitwasthrown.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.6.1ProjectileMotionHowfarawayistheplayerfromtheboard?page16512y�v�y0t�2gtLevel151.Youaccidentallythrowyourcarkeysandbecauseinitialvelocityiszero,horizontallyat8.0m/sfromacliff64-m�2yt����high.HowfarfromthebaseofthecliffgPhysics:PrinciplesandProblemsSolutionsManual127
131Chapter6continued(�2)(�0.32m)55.SwimmingYoutookarunningleapoffa������9.80m/s2high-divingplatform.Youwererunningat2.8m/sandhitthewater2.6slater.How�0.26shighwastheplatform,andhowfarfromNowx�vxttheedgeoftheplatformdidyouhitthe�(12.4m/s)(0.26s)water?Ignoreairresistance.�3.2m12y�v�yit�2gt54.ThetwobaseballsinFigure6-13werehit�0(2.6s)��1(9.80m/s2)(2.6s)2withthesamespeed,25m/s.Drawseparate2graphsofyversustandxversustforeach��33m,sotheplatformis33mhighball.x�vxt�(2.8m/s)(2.6s)�7.3mALevel256.ArcheryAnarrowisshotat30.0°aboveByAthehorizontal.Itsvelocityis49m/s,andit60°hitsthetarget.yB30°a.WhatisthemaximumheightthearrowxA�xBwillattain?v2�v2�2gdyyi■Figure6-13Atthehighpointvy�0,soVerticalv.Time25(v)2y060�d��202g15(v2���isin�)102gCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Vertical(m)530�((49m/s)(sin30.0°))2����(2)(9.80m/s2)0014235�31mTime(s)b.ThetargetisattheheightfromwhichHorizontalv.Timethearrowwasshot.Howfarawayisit?8012y�v�60y0t�2gt30�butthearrowlandsatthesame4060�height,soHorizontal(m)201y�0and0�v�yi�2gt0014235sot�0orTime(s)2vyt��i�g2vin��is��g(2)(49m/s)(sin30.0°)����9.80m/s2�5.0s128SolutionsManualPhysics:PrinciplesandProblems
132Chapter6continuedandx�vbutvxtyi�0,so�(vicos�)(t)t�����2yg�(49m/s)(cos30.0°)(5.0s)(�2)(�1001m)�2.1�102m������29.80m/s57.HittingaHomeRunApitchedballishit�14.3sbyabatterata45°angleandjustclearstheb.Whatisthehorizontaldistancebetweenoutfieldfence,98maway.Ifthefenceisattheplaneandthevictimswhentheboxthesameheightasthepitch,findthevelocityisdropped?oftheballwhenitleftthebat.Ignoreairx�vxtresistance.1h1000mThecomponentsoftheinitialvelocity�(125km/h)������3600s1kmarevx�vicos�iandvyi�visin�i(14.3s)Nowx�vxt�(vicos�i)t,so�497mxt���vs�icoi59.DivingDiversinAcapulcodivefromacliffAndy�v�12,buty�0,sothatis61mhigh.Iftherocksbelowtheyit�2gtcliffextendoutwardfor23m,whatisthe10��vyi��2gt�tminimumhorizontalvelocityadivermust1havetocleartherocks?sot�0orv�yi�2gt�012y�v�yit�2gtFromabovev�1�x���0andsincevyi�0,isin�i�2g�vs�icoi�2yt����Multiplyingbyvgicos�igivesv2sin��1(�2)(�61m)iicos�i�2gx�0�����9.80�m/s2�2�gxsovi���(2)(sin��3.53si)(cos�i)x�vxtgxthus,v���i����(2)(sin�xi)(cos�i)v��x�t(9.80m/s2)(98m)23m���������(2)(sin45°)(cos45°)3.53s�31m/sat45°�6.5m/sLevel360.JumpShotAbasketballplayeristryingto58.At-SeaRescueAnairplanetraveling1001mmakeahalf-courtjumpshotandreleasestheabovetheoceanat125km/hisgoingtoballattheheightofthebasket.Assumingdropaboxofsuppliestoshipwreckedthattheballislaunchedat51.0°,14.0mvictimsbelow.fromthebasket,whatspeedmusttheplayergivetheball?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.HowmanysecondsbeforetheplaneisdirectlyoverheadshouldtheboxbeThecomponentsoftheinitialvelocitydropped?arevxi�vicos�iandvyi�visin�iy�v�12Nowx�vxit�(vicos�i)t,soyit�2gtPhysics:PrinciplesandProblemsSolutionsManual129
133Chapter6continuedxt���vs�icoiAndy�v�12,buty�0,soyit�2gt10��v�yi�2gt�tsot�0orv�12�0yi�2gtFromabove1xv0sin�i��2g��v�s���0icoiMultiplyingbyvicos�igivesv2(sin��1ii)(cos�i)�2gx�0gxsov���i����(2)(sin�i)(cos�i)(9.80m/s2)(14.0m)�������(2)(sin51.0°)(cos51.0°)�11.8m/s6.2CircularMotionpage166Level161.CarRacingA615-kgracingcarcompletesonelapin14.3saroundacirculartrackwitharadiusof50.0m.ThecarmovesataCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.constantspeed.a.Whatistheaccelerationofthecar?v2a�c�r4�2r��T24�2(50.0m)���(14.3s)2�9.59m/s2b.Whatforcemustthetrackexertonthetirestoproducethisacceleration?F2)c�mac�(615kg)(9.59m/s�5.90�103N130SolutionsManualPhysics:PrinciplesandProblems
134Chapter6continued62.HammerThrowAnathletewhirlsa(4�2)(0.050m)2����0.61m/s7.00-kghammer1.8mfromtheaxisof(1.80s)2rotationinahorizontalcircle,asshowninr�10.0cm:Figure6-14.Ifthehammermakesonerev-4�2r(4�2)(0.100m)olutionin1.0s,whatisthecentripetala�����c�T2(1.80s)2accelerationofthehammer?Whatisthetensioninthechain?�1.22m/s2r�15.0cm:vtang4�2r(4�2)(0.150m)a�����c�T2(1.80s)2�1.83m/s2c.Whatforceacceleratesthecoin?frictionalforcebetweencoinandrecordd.Atwhichofthethreeradiiinpartbwouldthecoinbemostlikelytoflyoff■Figure6-14theturntable?Why?2r15.0cm,thelargestradius;the4�a�c�T2frictionforceneededtoholditisthegreatest.(4�2)(1.8m)���(1.0s)264.Arotatingrodthatis15.3cmlongisspun�71m/s2withitsaxisthroughoneendoftherodsoFthattheotherendoftherodhasaspeedofc�mac2010m/s(4500mph).�(7.00kg)(71m/s2)a.Whatisthecentripetalaccelerationof�5.0�102Ntheendoftherod?v2(2010m/s)2Level2a���c��r0.153m63.Acoinisplacedonavinylstereorecordthatismaking33�1�revolutionsperminute�2.64�107m/s23onaturntable.b.Ifyouweretoattacha1.0-gobjecttoa.Inwhatdirectionistheaccelerationoftheendoftherod,whatforcewouldbethecoin?neededtoholditontherod?TheaccelerationistowardtheFc�maccenteroftherecord.�(0.0010kg)(2.64�107m/s2)b.Findthemagnitudeoftheacceleration4N�2.6�10whenthecoinisplaced5.0,10.0,and15.0cmfromthecenteroftherecord.65.Frictionprovidestheforceneededforacar11totravelaroundaflat,circularracetrack.T�����f133��rev�minWhatisthemaximumspeedatwhichacarCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3cansafelytraveliftheradiusofthetrackis60s�(0.0300min)����1.80s80.0mandthecoefficientoffrictionis0.40?1minFr�5.0cm:c�Ff��FN��mg4�2rmv2mv2ac���2ButFc��r,thus�r��mg.TPhysics:PrinciplesandProblemsSolutionsManual131
135Chapter6continuedThemassofthecardividesouttogivev2a���gv2��gr,soc�gorrv2v����grsor���g��(0.40)�(9.80�m/s�2)(80.0�m)�2(120m/s)����18m/s9.80m/s2�1.5�103mLevel366.Acarnivalclownridesamotorcycledownarampandaroundaverticalloop.Ifthe6.3RelativeVelocityloophasaradiusof18m,whatisthepages166–167slowestspeedtheridercanhaveatthetopLevel1ofthelooptoavoidfalling?Hint:Atthis68.NavigatinganAirplaneAnairplanefliesslowestspeed,thetrackexertsnoforceontheat200.0km/hrelativetotheair.Whatismotorcycleatthetopoftheloop.thevelocityoftheplanerelativetotheFc�mac�Fg�mg,sogroundifitfliesduringthefollowingwindaconditions?c�ga.a50.0-km/htailwindv2���g,sorTailwindisinthesamedirectionastheairplanev��gr�200.0km/h�50.0km/h�250.0km/h��(9.80��m/s2)(18m�)�b.a50.0-km/hheadwind�13m/sHeadwindisintheoppositedirectionoftheairplane67.A75-kgpilotfliesaplaneinaloopasshown200.0km/h�50.0km/h�150.0km/hinFigure6-15.Atthetopoftheloop,whentheplaneiscompletelyupside-downforanCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.69.OdinaandLaToyaaresittingbyariverandinstant,thepilothangsfreelyintheseatdecidetohavearace.Odinawillrundownanddoesnotpushagainsttheseatbelt.Thetheshoretoadock,1.5kmaway,thenturnairspeedindicatorreads120m/s.Whatisaroundandrunback.LaToyawillalsoracetheradiusoftheplane’sloop?tothedockandback,butshewillrowaboatintheriver,whichhasacurrentofvtang�120m/s2.0m/s.IfOdina’srunningspeedisequaltoLaToya’srowingspeedinstillwater,whichis4.0m/s,whowillwintherace?Assumethattheybothturninstantaneously.xx�vt,sot��vforOdina,3.0�103mt���4.0m/s■Figure6-15�7.5�102sBecausethenetforceisequaltotheForLaToya(assumeagainstcurrentonweightofthepilot,thewaytothedock),xxFc�mac�Fg�mg,sot���1�2vv12132SolutionsManualPhysics:PrinciplesandProblems
136Chapter6continued1.5�103m1.5�103m�1vb/air����������tan���4.0m/s�2.0m/s4.0m/s�2.0m/svair�1.0�103s�115m/s�tan���6.5m/sOdinawins.�67°fromthehorizontowardthewestLevel270.CrossingaRiverYourowaboat,suchasLevel3theoneinFigure6-16,perpendicularto72.BoatingYouareboatingonariverthattheshoreofariverthatflowsat3.0m/s.flowstowardtheeast.BecauseofyourThevelocityofyourboatis4.0m/srelativeknowledgeofphysics,youheadyourboattothewater.53°westofnorthandhaveavelocityof6.0m/sduenorthrelativetotheshore.a.Whatisthevelocityofthecurrent?vtan�����w/s,sovbb/svvwvw/s�(tan�)(vb/s)�(tan53°)(6.0m/s)�8.0m/seast■Figure6-16b.Whatisthespeedofyourboatrelativea.Whatisthevelocityofyourboatrelativetothewater?totheshore?vv��2��(v�2cos���b�/s,sob/s�(vb/w)w/s)vb/w��(4.0m��/s)2��(3.0m/s)�2vb/sv��b/w�cos��5.0m/s6.0m/sv�����tan�1���b/wcos53°vw/s1m/s�1.0�10�14.0m/s�tan���3.0m/s73.AirTravelYouarepilotingasmallplane,�53°fromshoreandyouwanttoreachanairport450kmb.Whatisthecomponentofyourvelocityduesouthin3.0h.Awindisblowingfromparalleltotheshore?Perpendicularthewestat50.0km/h.Whatheadingandtoit?airspeedshouldyouchoosetoreachyourdestinationintime?3.0m/s;4.0m/sds450kmv�����150km/h71.StudyingtheWeatherAweatherstations�t3.0hreleasesaballoontomeasurecloudcondi-vp��(150k��m/h)2��(50�.0km/h)�2tionsthatrisesataconstant15m/srelativetotheair,butthereisalsoawindblowing�1.6�102km/hat6.5m/stowardthewest.Whatarethev��tan�1���windmagnitudeanddirectionofthevelocityofvCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.stheballoon?�150.0km/hv���)2�(v�2�tan����150km/hb�(vb/airair)�18°westofsouth��(15m��/s)2��(6.5m�/s)2�16m/sMixedReviewPhysics:PrinciplesandProblemsSolutionsManual133
137Chapter6continuedpage167Level174.EarlyskepticsoftheideaofarotatingEarthsaidthatthefastspinofEarthwouldthrowpeopleattheequatorintospace.TheradiusofEarthisabout6.38�103km.Showwhythisideaiswrongbycalculatingthefollowing.a.thespeedofa97-kgpersonattheequator�d2�r2�(6.38�106m)v���������tT3600s(24h)����1h�464m/sb.theforceneededtoacceleratethepersoninthecircleFc�macmv2��r(97kg)(464m/s)2����6.38�106m�3.3Nc.theweightofthepersonFg�mg�(97)(9.80m/s2)�9.5�102Nd.thenormalforceofEarthontheperson,thatis,theperson’sapparentweightF2N�3.3NN�9.5�10�9.5�102NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.75.FiringaMissileAnairplane,movingat375m/srelativetotheground,firesamissileforwardataspeedof782m/srelativetotheplane.Whatisthespeedofthemissilerelativetotheground?vm/g�vp/g�vm/p�375m/s�782m/s�1157m/s76.RocketryArocketinouterspacethatismovingataspeedof1.25km/srelativetoanobserverfiresitsmotor.Hotgasesareexpelledoutthebackat2.75km/srelativetotherocket.Whatisthespeedofthegasesrelativetotheobserver?vg/o�vr/o�vg/r1.25km/s�(�2.75km/s)��1.50km/sLevel277.Twodogs,initiallyseparatedby500.0m,arerunningtowardseachother,eachmovingwithaconstantspeedof2.5m/s.Adragonfly,movingwithaconstantspeedof3.0m/s,fliesfromthenoseofonedogtotheother,thenturnsaround134SolutionsManualPhysics:PrinciplesandProblems
138Chapter6continuedinstantaneouslyandfliesbacktotheotherFor35mph:dog.ItcontinuestoflybackandforthuntilFc�Fgthedogsrunintoeachother.Whatdistancedoesthedragonflyflyduringthistime?mv2�cos��mgsin�rThedogswillmeetinv2sin�500.0m2s�r�g��cos����gtan���1.0�105.0m/sv2Thedragonflyflies��tan�1���gr(3.0m/s)(1.0�102s)�3.0�102m.(15.7m/s)2�tan�1�����(9.80m/s2)(56.0m)78.A1.13-kgballisswungverticallyfroma0.50-mcordinuniformcircularmotion�34.9°ataspeedof2.4m/s.WhatisthetensioninFor45mph:thecordatthebottomoftheball’smotion?2�1v��tan���FgrT�Fg�Fc2�1(20.1m/s)2�mg��mv�tan�����2)(36.0m)r(9.80m/s�(1.13kg)(9.80m/s2)��48.9°(1.13kg)(2.4m/s)2Level3���0.50m80.The1.45-kgballinFigure6-17is�24Nsuspended14.0°froma0.80-79.BankedRoadsCurvesonroadsoftenaremstringbankedtohelppreventcarsfromslippingandofftheroad.Ifthepostedspeedlimitforaswunginaparticularcurveofradius36.0mis15.7m/s■Figure6-17horizontal(35mph),atwhatangleshouldtheroadbecircleataconstantbankedsothatcarswillstayonacircularspeedsuchthatthestringmakesananglepatheveniftherewerenofrictionbetweenof14.0°withthevertical.theroadandthetires?Ifthespeedlimitwasa.Whatisthetensioninthestring?increasedto20.1m/s(45mph),atwhatFangleshouldtheroadbebanked?Tcos��mgmgsoF��T�cos�(1.45m/s)(9.80m/s2)����cos14.0°�14.6Nb.Whatisthespeedoftheball?mv2F�c�FTsin���rFg�FTcos��mgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.FTsin�mv2so����Fcos�rmgTv2ortan���rgPhysics:PrinciplesandProblemsSolutionsManual135
139Chapter6continuedsov���rgtan����(0.80�m)(9.8��0m/s2�)(tan�14.0°)��1.4m/s81.Abaseballishitdirectlyinlinewithanoutfielderatanangleof35.0°abovethehorizontalwithaninitialvelocityof22.0m/s.Theoutfielderstartsrunningassoonastheballishitataconstantvelocityof2.5m/sandbarelycatchestheball.Assumingthattheballiscaughtatthesameheightatwhichitwashit,whatwastheinitialseparationbetweenthehitterandoutfielder?Hint:Therearetwopossibleanswers.�x�vxit�vpt�t(vxi�vp)Togett,y�v�12,y�0yit�2gtsov�12,t�0oryit�2gt1v�yi�2gt2vyit���g2vin��is��g2vin�so�x�is�(v�gxi�vp)2vin���is�(vCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.gicos��vp)(2)(22.0m/s)(sin35.0°)������29.80m/s((22.0m/s)(cos35.0°)�2.5m/s)�53mor4.0�101m82.AJewelHeistYouareservingasatechnicalconsultantforalocallyproducedcartoon.Inoneepisode,twocrimi-nals,ShiftyandLefty,havestolensomejewels.Leftyhasthejewelswhenthepolicestarttochasehim,andherunstothetopofa60.0-mtallbuildinginhisattempttoescape.Meanwhile,Shiftyrunstotheconvenienthot-airballoon20.0mfromthebaseofthebuildingandunteth-ersit,soitbeginstoriseataconstantspeed.Leftytossesthebagofjewelshorizontallywithaspeedof7.3m/sjustastheballoon136SolutionsManualPhysics:PrinciplesandProblems
140Chapter6continuedbeginsitsascent.WhatmustthevelocityoftheballoonbeforShiftytoeasilycatchthebag?x�x�v��xit,sot�vxi�y�12,butvbag�vyit�2gtyi�012so�y�bag��2gt�yv�ba�lloonballoon�t60.0m��ybag���t1260.0m���gt2���t60.0m1����gtt260.0m1x����g���x�2vxivxi(60.0m)vxigx������x2vxi(60.0m)(7.3m/s)�����(20.0m)(�9.80m/s)(20.0m)���2(7.3m/s)�8.5m/sThinkingCriticallypage16883.ApplyConceptsConsideraroller-coasterloopliketheoneinFigure6-18.Arethecarstravelingthroughtheloopinuniformcircularmotion?Explain.■Figure6-18Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Theverticalgravitationalforcechangesthespeedofthecars,sothemotionisnotuniformcircularmotion.84.UseNumbersA3-pointjumpshotisreleased2.2mabovethegroundand6.02mfromthebasket.Thebasketis3.05mabovethefloor.Forlaunchanglesof30.0°and60.0°,findthespeedtheballneedstobethrowntomakethebasket.Physics:PrinciplesandProblemsSolutionsManual137
141Chapter6continuedxxa.Isthehitahomerun?x�v�����ixt,sot�vvos�ixicYes,thehitisahomerun;theball12clearsthewallby2.1m.�y�v�iyt�2gtb.Whatistheminimumspeedatwhichx1x2theballcouldbehitandclearthewall?�visin���vos�����2g��vos���icicgxv����gx2i�cos���2((tan��)x���y)�xtan����2v2(cos�)2i96.0���xgmcos29.80m/s2sovi��cos�����2((tan��)�x���y)����������6°(2)((tan26°)(96.0m)�13m)For��30.0°�41m/s6.02c.Iftheinitialvelocityoftheballis42.0v�mi��cos3m/s,forwhatrangeofangleswillthe�����9.80m/s20.0°ballgooverthewall?�����.02m)�(3.05m�2.2m))Fortheballtogooverthewall,the�9.5m/srangeofanglesneedstobe25°�70°.For��60.0°87.AnalyzeAlbertEinsteinshowedthatthe6.02vi���cos62ruleyoulearnedfortheadditionofveloci-m�9.80m/s�0.0°�����2((tan60°(6.02m)������(3.05m�2.2m))tiesdoesnotworkforobjectsmovingnearthespeedoflight.Forexample,ifarocket�8.6m/smovingatvelocityvAreleasesamissilethathasvelocityv85.AnalyzeForwhichangleinproblem84isBrelativetotherocket,thenthevelocityofthemissilerelativetoanitmoreimportantthattheplayerobserverthatisatrestisgivenbyv�(vgetthespeedright?Toexplorethisques-A�v2),wherecisthespeedoftion,varythespeedateachanglebyB)/(1�vAvB/c8m/s.Thisformulagivesthelight,3.00�10Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.5percentandfindthechangeintherangecorrectvaluesforobjectsmovingatslowoftheattemptedshot.speedsaswell.SupposearocketmovingatVaryingspeedby5percentat30.0°11km/sshootsalaserbeamoutinfrontofchangesRbyabout0.90mineitherit.Whatspeedwouldanunmovingobserv-direction.At60.0°itchangesRbyonlyerfindforthelaserlight?Supposethataabout0.65m.Thus,thehighlaunchrocketmovesataspeedc/2,halfthespeedangleislesssensitivetospeedvaria-oflight,andshootsamissileforwardatations.speedofc/2relativetotherocket.Howfastwouldthemissilebemovingrelativetoa86.ApplyComputersandCalculatorsAbase-fixedobserver?ballplayerhitsabelt-high(1.0m)fastball(vdowntheleft-fieldline.Theballishitwithanv�r/o���vl/r)l/o�vr/o�v1/rinitialvelocityof42.0m/sat26°.Theleft-field�1��c�2�wallis96.0mfromhomeplateatthefoulpoleandis14-mhigh.Writetheequationfor1.1�104m/s�3.00�108m/s�theheightoftheball,y,asafunctionofits(1.1�104m/s)(3.00�108m/s)1�����distancefromhomeplate,x.Useacomputer(3.00�108m/s)2orgraphingcalculatortoplotthepathofthe8m/s�3.0�10ball.Tracealongthepathtofindhowhighv�vabovethegroundtheballiswhenitisatther/om/rvm/o���vvwall.1��r/o�m/rc2138SolutionsManualPhysics:PrinciplesandProblems
142Chapter6continuedccisoutwardwhilethetensionisinward.�����22Thus,thetensionexertedbythestring���c����c��mustbeevenlarger.221��2cWritinginPhysics4��cpage168589.RollerCoastersIfyoutakealookatverti-88.AnalyzeandConcludeAballonalightcalloopsonrollercoasters,youwillnoticestringmovesinaverticalcircle.Analyzeandthatmostofthemarenotcircularinshape.describethemotionofthissystem.BesureResearchwhythisissoandexplainthetoconsidertheeffectsofgravityandten-physicsbehindthisdecisionbythecoastersion.Isthissysteminuniformcircularengineers.motion?Explainyouranswer.mv2Answerswillvary.SinceF��,asvc�rItisnotuniformcircularmotion.decreasesduetogravitywhengoingGravityincreasesthespeedoftheballuphill,risreducedtokeeptheforcewhenitmovesdownwardandreducesconstant.thespeedwhenitismovingupward.Therefore,thecentripetalacceleration90.Manyamusement-parkridesutilizecen-neededtokeepitmovinginacircletripetalaccelerationtocreatethrillsforwillbelargeratthebottomandsmall-thepark’scustomers.Choosetworideseratthetopofthecircle.Atthetop,otherthanrollercoastersthatinvolvetensionandgravityareinthesamecircularmotionandexplainhowthedirection,sothetensionneededwillphysicsofcircularmotioncreatesthebeevensmaller.Atthebottom,gravitysensationsfortheriders.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual139
143
144CHAPTER7GravitationPracticeProblems7.1PlanetaryMotionandGravitationpages171–178page1741.IfGanymede,oneofJupiter’smoons,hasaperiodof32days,howmanyunitsarethereinitsorbitalradius?UsetheinformationgiveninExampleProblem1.T2r3��G�����G��TrII3332days2rG��(4.2u��nits)�����1.8days��33un3��23.4��10��its�29units2.AnasteroidrevolvesaroundtheSunwithameanorbitalradiustwicethatofEarth’s.PredicttheperiodoftheasteroidinEarthyears.T2r3��a��a��T��r�withra�2rEEEr3T�aT2a�����r��EE2r3������E��(1.0�y)2rE�2.8y3.FromTable7-1,onpage173,youcanfindthat,onaverage,Marsis1.52timesasfarfromtheSunasEarthis.PredictthetimerequiredforMarstoorbittheSuninEarthdays.T2r3�M���M��T��r�withrM�1.52rEEEr31.52r3Thus,T�MT2���E(365days)2M�����r��E���r����EE��4.68���105days�2�684days4.TheMoonhasaperiodof27.3daysandameandistanceof3.90�105kmfromCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thecenterofEarth.a.UseKepler’slawstofindtheperiodofasatelliteinorbit6.70�103kmfromthecenterofEarth.T2r3��s��s�����TrMMPhysics:PrinciplesandProblemsSolutionsManual141
145Chapter7continuedr3T�sT2s�����r��MM6.70�103km32���(27.3days)���3.90�1�05km������3.78��10��3�days2�6.15�10�2days�88.6minb.HowfaraboveEarth’ssurfaceisthissatellite?h�rs�rE�6.70�106m�6.38�106m�3.2�105m�3.2�102km5.UsingthedatainthepreviousproblemfortheperiodandradiusofrevolutionoftheMoon,predictwhatthemeandistancefromEarth'scenterwouldbeforanartificialsatellitethathasaperiodofexactly1.00day.T2r3���s����s��TrMM33Ts235km31.00days2rs��r�M��T�����(3.90���10)���27.�3�days��M313k3��7.96��10��m�4.30�104kmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.SectionReview7.1PlanetaryMotionandGravitationpages171–178page1786.Neptune’sOrbitalPeriodNeptuneorbitstheSunwithanorbitalradiusof4.495�1012m,whichallowsgases,suchasmethane,tocondenseandformanatmosphere,asshowninFigure7-8.IfthemassoftheSunis1.99�1030kg,calculatetheperiodofNeptune’sorbit.r3T�2����GmS(4.495�1012m)3■Figure7-8�2����������(6.67�10�11N�m2/kg2)(1.99�1030kg)�5.20�109s�6.02�105days7.GravityIfEarthbegantoshrink,butitsmassremainedthesame,whatwouldhappentothevalueofgonEarth’ssurface?Thevalueofgwouldincrease.142SolutionsManualPhysics:PrinciplesandProblems
146Chapter7continued8.GravitationalForceWhatisthegravitationalforcebetweentwo15-kgpackagesthatare35cmapart?Whatfractionisthisoftheweightofonepackage?mmF�E�g�Gr2(6.67�10�11N�m2�kg2)(15kg)2�����(0.35m)2�1.2�10�7NBecausetheweightismg�147N,thegravitationalforceis8.2�10�10or0.82partsperbillionoftheweight.9.UniversalGravitationalConstantCavendishdidhisexperimentusingleadspheres.Supposehehadreplacedtheleadsphereswithcopperspheresofequalmass.WouldhisvalueofGbethesameordifferent?Explain.Itwouldbethesame,becausethesamevalueofGhasbeenusedsuccessfullytodescribetheattractionofbodieshavingdiversechemicalcompositions:theSun(astar),theplanets,andsatellites.10.LawsorTheories?Kepler’sthreestatementsandNewton’sequationforgravitationalattractionarecalled“laws.”Weretheyevertheories?Willtheyeverbecometheories?No.Ascientificlawisastatementofwhathasbeenobservedtohappenmanytimes.Atheoryexplainsscientificresults.Noneofthesestatementsoffersexplanationsforwhythemotionofplanetsareastheyareorforwhygravitationalattractionactsasitdoes.11.CriticalThinkingPickinguparockrequireslesseffortontheMoonthanonEarth.a.HowwilltheweakergravitationalforceontheMoon’ssurfaceaffectthepathoftherockifitisthrownhorizontally?Horizontalthrowingrequiresthesameeffortbecausetheinertialcharacter,F�ma,oftherockisinvolved.Themassoftherockdependsonlyontheamountofmatterintherock,notonitslocationintheuniverse.Thepathwouldstillbeaparabola,butitcouldbemuchwiderbecausetherockwouldgofartherbeforeithitstheground,giventhesmalleraccelerationrateandlongertimeofflight.b.Ifthethroweraccidentallydropstherockonhertoe,willithurtmoreorlessthanitwouldonEarth?Explain.AssumetherockswouldbedroppedfromthesameheightonEarthandontheMoon.ItwillhurtlessbecausethesmallervalueofgontheMoonmeansthattherockstrikesthetoewithasmallervelocitythanonEarth.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual143
147Chapter7continuedPracticeProblems7.2UsingtheLawofUniversalofGravitationpages179–185page181Forthefollowingproblems,assumeacircularorbitforallcalculations.12.SupposethatthesatelliteinExampleProblem2ismovedtoanorbitthatis24kmlargerinradiusthanitspreviousorbit.Whatwoulditsspeedbe?Isthisfasterorslowerthanitspreviousspeed?r�(h�2.40�104m)�rE�(2.25�105m�2.40�104m)�6.38�106m�6.63�106mGmv�����Er(6.67�10�11N�m2/kg2)(5.97�1024kg)����������6.63�106m�7.75�103m/s,slower13.UseNewton’sthoughtexperimentonthemotionofsatellitestosolvethefollowing.a.CalculatethespeedthatasatelliteshotfromacannonmusthavetoorbitEarth150kmaboveitssurface.GmE(6.67�10�11N�m2/kg2)(5.97�1024kg)v�����������r����(6.38�106m�1.5�105m)�7.8�103m/sb.Howlong,insecondsandminutes,wouldittakeforthesatellitetocompleteoneorbitandreturntothecannon?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.r3(6.38�106m�1.5�105m)3T�2���2��������GmE����(6.67�10�11N�m2/kg2)(5.97�1024kg)�5.3�103s�88min14.UsethedataforMercuryinTable7-1onpage173tofindthefollowing.a.thespeedofasatellitethatisinorbit260kmaboveMercury’ssurfaceGmv�����Mrr�rM�260km�2.44�106m�0.26�106m�2.70�106m(6.67�10�11N�m2/kg2)(3.30�1023kg)v����������2.70�106m�2.86�103m/sb.theperiodofthesatelliter3(2.70�106m)3T�2���2��������GmM����(6.67�10�11N�m2/kg2)(3.30�1023kg)�5.94�103s�1.65h144SolutionsManualPhysics:PrinciplesandProblems
148Chapter7continuedSectionReview7.2UsingtheLawofUniversalofGravitationpages179–185page18515.GravitationalFieldsTheMoonis3.9�105kmfromEarth’scenterand1.5�108kmfromtheSun’scenter.ThemassesofEarthandtheSunare6.0�1024kgand2.0�1030kg,respectively.a.FindtheratioofthegravitationalfieldsduetoEarthandtheSunatthecenteroftheMoon.mGravitationalfieldduetotheSun:g��SS�Gr2SmGravitationalfieldduetoEarth:g��EE�Gr2Egmr2��S����S���E��gmr2EES(2.0�1030kg)(3.9�105km)2�����(6.0�1024kg)(1.5�108km)2�2.3b.WhentheMoonisinitsthirdquarterphase,asshowninFigure7-17,itsdirectionfromEarthisatrightanglestotheSun’sdirection.WhatisthenetgravitationalfieldduetotheSunandEarthatthecenteroftheMoon?MoonSunEarth■Figure7-17Becausethedirectionsareatrightangles,thenetfieldisthesquarerootofthesumofthesquaresofthetwofields.Gmg��SS�r2(6.67�10�11N�m2�kg2)(2.0�1030kg)�����(1.5�1011m)2�5.9�10�3N/kgSimilarly,g�3N/kgE�2.6�10gnet��(5.9���10�3�N/kg)2��(2.6��10��3N/kg)�2�6.4�10�3N/kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.16.GravitationalFieldThemassoftheMoonis7.3�1022kganditsradiusis1785km.WhatisthestrengthofthegravitationalfieldonthesurfaceoftheMoon?GM(6.67�10�11N�m2�kg2)(7.3�1022kg)g���������r2(1.785�103m)2�1.5N/kg,aboutone-sixththatonEarthPhysics:PrinciplesandProblemsSolutionsManual145
149Chapter7continued17.ASatellite’sMassWhenthefirstartificialsatellitewaslaunchedintoorbitbytheformerSovietUnionin1957,U.S.presidentDwightD.Eisenhoweraskedhisscientificadvisorstocalculatethemassofthesatellite.Wouldtheyhavebeenabletomakethiscalculation?Explain.No.Becausethespeedandperiodoftheorbitdon’tdependatallonthemassofthesatellite,thescientificadvisorswouldnothavebeenabletocalculatethemassofthesatellite.18.OrbitalPeriodandSpeedTwosatellitesareincircularorbitsaboutEarth.Oneis150kmabovethesurface,theother160km.a.Whichsatellitehasthelargerorbitalperiod?Whentheorbitalradiusislarge,theperiodalsowillbelarge.Thus,theoneat160kmwillhavethelargerperiod.b.Whichonehasthegreaterspeed?Theoneat150km,becausethesmallertheorbitalradius,thegreaterthespeed.19.TheoriesandLawsWhyisEinstein’sdescriptionofgravitycalleda“theory,”whileNewton’sisa“law?”Newton’slawdescribeshowtocalculatetheforcebetweentwomassiveobjects.Einstein’stheoryexplainshowanobject,suchasEarth,attractstheMoon.20.WeightlessnessChairsinanorbitingspacecraftareweightless.Ifyouwereonboardsuchaspacecraftandyouwerebarefoot,wouldyoustubyourtoeifyoukickedachair?Explain.Yes.Thechairsareweightlessbutnotmassless.TheystillhaveinertiaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.andcanexertcontactforcesonyourtoe.21.CriticalThinkingItiseasiertolaunchasatellitefromEarthintoanorbitthatcircleseastwardthanitistolaunchonethatcircleswestward.Explain.Earthrotatestowardtheeast,anditsvelocityaddstothevelocitygiventothesatellitebytherocket,therebyreducingthevelocitythattherocketmustsupply.ChapterAssessmentConceptMappingpage19022.Createaconceptmapusingtheseterms:planets,stars,Newton’slawofuniversalgravitation,Kepler’sfirstlaw,Kepler’ssecondlaw,Kepler’sthirdlaw,Einstein’sgeneraltheoryofrelativity.146SolutionsManualPhysics:PrinciplesandProblems
150Chapter7continuedEinstein’sgeneraltheoryofrelativityExplainsNewton’slawofuniversalgravitationSupportsKepler’sfirstKepler’ssecondKepler’sthirdlawlawlawRelatesperiodsandDescribesmotionofradiiofplanetsmovingaroundstarsKepler’sfirstandsecondlawsdescribethemotionofasingleplanet.Kepler’sthirdlawdescribestheperiodsversustheorbitalradiiofallplanetsaroundastar.Newton’slawofuniversalgravitationsupportsKepler’slaws.Einstein’stheoryexplainsNewton’sandKepler’slaws.MasteringConceptspage19023.In1609,GalileolookedthroughhistelescopeatJupiterandsawfourmoons.ThenameofoneofthemoonsthathesawisIo.RestateKepler’sfirstlawforIoandJupiter.(7.1)ThepathofIoisanellipse,withJupiteratonefocus.24.EarthmovesmoreslowlyinitsorbitduringsummerinthenorthernhemisphereCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thanitdoesduringwinter.IsitclosertotheSuninsummerorinwinter?(7.1)BecauseEarthmovesmoreslowlyinitsorbitduringsummer,byKepler’ssecondlaw,itmustbefartherfromtheSun.Therefore,EarthisclosertotheSuninthewintermonths.Physics:PrinciplesandProblemsSolutionsManual147
151Chapter7continued25.Istheareasweptoutperunitoftimeby32.WhatprovidestheforcethatcausestheEarthmovingaroundtheSunequaltocentripetalaccelerationofasatelliteintheareasweptoutperunitoftimebyMarsorbit?(7.2)movingaroundtheSun?(7.1)gravitationalattractiontothecentralNo.Theequalityoftheareasweptoutbodyperunitoftimeappliestoeachplanetindividually.33.Duringspaceflight,astronautsoftenrefertoforcesasmultiplesoftheforceofgravityon26.WhydidNewtonthinkthataforcemustactEarth’ssurface.Whatdoesaforceof5gontheMoon?(7.1)meantoanastronaut?(7.2)NewtonknewthattheMoonfollowedAforceof5gmeansthatanastronaut’sacurvedpath;therefore,itwasweightisfivetimesheavierthanitisonaccelerated.HealsoknewthataEarth.Theforceexertedontheastro-forceisrequiredforacceleration.nautisfivetimestheforceofEarth’sgravitationalforce.27.HowdidCavendishdemonstratethatagravitationalforceofattractionexists34.Newtonassumedthatagravitationalforcebetweentwosmallobjects?(7.1)actsdirectlybetweenEarthandtheMoon.Hecarefullymeasuredthemasses,theHowdoesEinstein’sviewoftheattractivedistancebetweenthemasses,andtheforcebetweenthetwobodiesdifferfromforceofattraction.HethencalculatedNewton’sview?(7.2)GusingNewton’slawofuniversalgrav-Einstein’sviewisthatgravityisanitation.effectofthecurvatureofspaceasaresultofthepresenceofmass,whereas28.WhathappenstothegravitationalforceNewton’sviewofgravityisthatitisabetweentwomasseswhenthedistanceforceactingdirectlybetweenobjects.betweenthemassesisdoubled?(7.1)Thus,accordingtoEinstein,theAccordingtoNewton,F�1/r2.IftheattractionbetweenEarthandtheMoonCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.distanceisdoubled,theforceiscuttoistheeffectofcurvatureofspaceone-fourth.causedbytheircombinedmasses.29.AccordingtoNewton’sversionofKepler’s35.Showthatthedimensionsofginthethirdlaw,howwouldtheratioT2/r3changeequationg�F/mareinm/s2.(7.2)ifthemassoftheSunweredoubled?(7.1)2FNkg�m/s2BecauseT2/r3�4�2/GmTheunitsof��are����m/sS,ifthemassmkgkgoftheSun,mS,isdoubled,theratiowillbehalved.36.IfEarthweretwiceasmassivebutremainedthesamesize,whatwouldhappentothe30.Howdoyouanswerthequestion,“Whatvalueofg?(7.2)keepsasatelliteup?”(7.2)Thevalueofgwoulddouble.Itsspeed;itisfallingallthetime.ApplyingConcepts31.AsatelliteisorbitingEarth.Onwhichofpages190–191thefollowingdoesitsspeeddepend?(7.2)37.GolfBallTheforceofgravityactingonana.massofthesatelliteobjectnearEarth’ssurfaceisproportionalb.distancefromEarthtothemassoftheobject.Figure7-18c.massofEarthshowsatennisballandgolfballinfreefall.WhydoesatennisballnotfallfasterthanaSpeeddependsonlyonb,thedistancegolfball?fromtheEarth,andc,themassofEarth.148SolutionsManualPhysics:PrinciplesandProblems
152Chapter7continued40.DecidewhethereachoftheorbitsshowninFigure7-19isapossibleorbitforaplanet.ccSunSunccSunSun■Figure7-18mF�G1m�2�r2■Figure7-19m1�Earth’smassOnlyd(lowerright)ispossible.Fa(topleft)andb(topright)donota��m2havetheSunatafocus,andinc(lowerleft),theplanetisnotinm2�object’smassorbitaroundtheSun.GmThus,a��1�r241.TheMoonandEarthareattractedtoeachTheaccelerationisindependentoftheotherbygravitationalforce.Doesthemore-object’smass.ThisisbecausemoremassiveEarthattracttheMoonwithamassiveobjectsrequiremoreforcetogreaterforcethantheMoonattractsEarth?accelerateatthesamerate.Explain.No.Theforcesconstituteanaction-38.Whatinformationdoyouneedtofindthereactionpair,sounderNewton’sthirdmassofJupiterusingNewton’sversionoflaw,theyareequalandopposite.Kepler’sthirdlaw?Youmustknowtheperiodandorbital42.WhatwouldhappentothevalueofGifradiusofatleastoneofitssatellites.Earthweretwiceasmassive,butremainedthesamesize?39.ThemassofPlutowasnotknownuntilaNothing.Gisauniversalconstant,andsatelliteoftheplanetwasdiscovered.Why?itisindependentofEarth’smass.OrbitalmotionofaplanetdoesnotHowever,theforceofattractionwoulddependonitsmassandcannotbedouble.usedtofindthemass.Asatelliteorbitingtheplanetisnecessaryto43.Figure7-20showsasatelliteorbitingEarth.findtheplanet’smass.GmEExaminetheequationv�����,relatingrthespeedofanorbitingsatelliteanditsdistancefromthecenterofEarth.DoesaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.satellitewithalargeorsmallorbitalradiushavethegreatervelocity?Physics:PrinciplesandProblemsSolutionsManual149
153Chapter7continued300g����3.Thus,gonJupiteristhree102SatellitetimesthatonEarth.47.AsatelliteisoneEarthradiusabovethesur-rfaceofEarth.HowdoestheaccelerationduetogravityatthatlocationcomparetoaccelerationatthesurfaceofEarth?Earthd�rE�rE�2rErE21so,a�g�����g2r4E■Figure7-20(Nottoscale)Asatellitewithasmallradiushasthe48.IfamassinEarth’sgravitationalfieldisgreatervelocity.doubled,whatwillhappentotheforceexertedbythefielduponthemass?44.SpaceShuttleIfaspaceshuttlegoesintoaItalsowilldouble.higherorbit,whathappenstotheshuttle’speriod?49.WeightSupposethatyesterdayyourbodyr3hadamassof50.0kg.ThismorningyouBecauseT�2����,iftheorbitalGmsteppedonascaleandfoundthatyouhadradiusincreases,sowilltheperiod.gainedweight.a.Whathappened,ifanything,toyour45.Marshasaboutone-ninththemassofmass?Earth.Figure7-21showssatelliteM,whichorbitsMarswiththesameorbitalradiusYourmassincreased.assatelliteE,whichorbitsEarth.Whichb.Whathappened,ifanything,totheratiosatellitehasasmallerperiod?ofyourweighttoyourmass?TheratioremainedconstantCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.becauseitisequaltothegravita-tionalfieldatthelocation,acon-MarsEarthstant�g.rMrE50.Asanastronautinanorbitingspaceshuttle,EMhowwouldyougoabout“dropping”anobjectdowntoEarth?■Figure7-21(Nottoscale)To“drop”anobjectdowntoEarth,your3BecauseT�2����,asthemassofwouldhavetolaunchitbackwardattheGmsamespeedatwhichyouaretravelingtheplanetincreases,theperiodoftheinorbit.WithrespecttoEarth,thesatellitedecreases.BecauseEarthobject’sspeedperpendiculartoEarth’shasalargermassthanMars,Earth’sgravitywouldbezero,anditcouldthensatellitewillhaveasmallerperiod.“drop”downtoEarth.However,theobjectislikelytoburnupasaresultof46.Jupiterhasabout300timesthemassoffrictionwithEarth’satmosphereontheEarthandabouttentimesEarth’sradius.waydown.EstimatethesizeofgonthesurfaceofJupiter.51.WeatherSatellitesTheweatherpicturesmg��E.IfJupiterhas300timesthethatyouseeeverydayonTVcomefromar2EspacecraftinastationarypositionrelativetomassandtentimestheradiusofEarth,150SolutionsManualPhysics:PrinciplesandProblems
154Chapter7continuedthesurfaceofEarth,35,700kmabovemmF�G�SJEarth’sequator.Explainhowitcanstayinr2exactlythesamepositiondayafterday.�(6.67�10�11N�m2/kg2)Whatwouldhappenifitwerecloser?Fartherout?Hint:Drawapictorialmodel.(5.9kg)(4.7�10�2kg)���(5.5�10�2m)2Thesatelliteispositionedasclosetotheequatoraspossiblesoitdoesn’t�6.1�10�9Nappeartohavemuchnorth-southmove-ment.Becauseitisplacedatthatdis-54.UseTable7-1onp.173tocomputethetance,thesatellitehasaperiodof24.0gravitationalforcethattheSunexertsonh.Ifitwerepositionedanycloser,itsJupiter.periodwouldbelessthan24.0handitm1m2F�G�wouldappeartomovetowardtheeast.r2Ifitwerepositionedanyfarther,itsperi-�(6.67�10�11N�m2/kg2)odwouldbelongerthan24.0h.(1.99�1030kg)(1.90�1027kg)����MasteringProblems(7.78�1011m)27.1PlanetaryMotionandGravitation�4.17�1023Npages191–19255.Tomhasamassof70.0kgandSallyhasaLevel1massof50.0kg.TomandSallyarestanding52.Jupiteris5.2timesfartherfromtheSun20.0mapartonthedancefloor.SallylooksthanEarthis.FindJupiter’sorbitalperiodupandseesTom.Shefeelsanattraction.IfinEarthyears.theattractionisgravitational,finditssize.TJ2rJ3AssumethatbothTomandSallycanbe�������TErEreplacedbysphericalmasses.mr3F�G�TmST�JT22J�����r��ErE�(6.67�10�11N�m2/kg2)5.23��������(1.0�y)2(70.0kg)(50.0kg)1.0��(20.0m)2��141y��2�10N�5.84�10�12y56.Twoballshavetheircenters2.0mapart,as53.Figure7-22showsaCavendishapparatusshowninFigure7-23.OneballhasamassliketheoneusedtofindG.Ithasalargeof8.0kg.Theotherhasamassof6.0kg.leadspherethatis5.9kginmassandaWhatisthegravitationalforcebetweenthem?smallonewithamassof0.047kg.Theircentersareseparatedby0.055m.Findtheforceofattractionbetweenthem.2.0m8.0kg6.0kg5.9kg■Figure7-230.047kgmF�G�1m2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.r20.055m0.055m�(6.67�10�11N�m2/kg2)(8.0kg)(6.0kg)��0.047kg(2.0m)25.9kg�8.0�10�10N■Figure7-22Physics:PrinciplesandProblemsSolutionsManual151
155Chapter7continued57.TwobowlingballseachhaveamassofFr2m�6.8kg.TheyarelocatednexttoeachotherE�Gmwiththeircenters21.8cmapart.Whatgrav-(9.8N)(6.4�106m)2itationalforcedotheyexertoneachother?�����(6.67�10�11N�m2�kg2)(1.0kg)mF�G�1m2�6.0�1024kgr2b.CalculatetheaveragedensityofEarth.�(6.67�10�11N�m2/kg2)(6.8kg)(6.8kg)��43�(4�)(6.4�106m)3(0.218m)2V���r���33�6.5�10�8N21m3�1.1�1058.Assumethatyouhaveamassof50.0kg.m6.0�1024kgD������24kgandaV1.1�1021m3Earthhasamassof5.97�10radiusof6.38�106m.�5.5�103kg/m3a.Whatistheforceofgravitationalattrac-61.UranusUranusrequires84yearstocircletionbetweenyouandEarth?theSun.FindUranus’sorbitalradiusasaSampleanswer:multipleofEarth’sorbitalradius.mSmET2r3F�G��2��U���U�r���TrEE�(6.67�10�11N�m2/kg2)rU3TU2(50.0kg)(5.97�1024kg)�r������T�����EE(6.38�106m)2384y2�489N��������1.0yb.Whatisyourweight?�19Sampleanswer:SorF2)U�19rEg�mg�(50.0kg)(9.80m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�4.90�102N62.VenusVenushasaperiodofrevolutionof225Earthdays.Findthedistancebetween59.ThegravitationalforcebetweentwoelectronstheSunandVenusasamultipleofEarth’sthatare1.00mapartis5.54�10�71N.Findorbitalradius.themassofanelectron.T2r3���V����V��F�G�m1m2,wheremTErEr21�m2�merV3TV2Fr2���������Some����rETEG3225days2(5.54�10�71N)(1.00m)2������������365days���6.67�10�11N�m2/kg2�9.11�10�31kg�0.724SorV�0.724rE60.A1.0-kgmassweighs9.8NonEarth’ssur-face,andtheradiusofEarthisroughlyLevel26.4�106m.63.Ifasmallplanet,D,werelocated8.0timesasfarfromtheSunasEarthis,howmanyyearsa.CalculatethemassofEarth.wouldittaketheplanettoorbittheSun?mF�G�1m2T2r3r2���D����D��TrEE152SolutionsManualPhysics:PrinciplesandProblems
156Chapter7continuedrD328.032T��T���(1.0y)�23yearsD����r��E���1.0���E64.Twospheresareplacedsothattheircentersare2.6mapart.Theforcebetweenthetwospheresis2.75�10�12N.Whatisthemassofeachsphereifonesphereistwicethemassoftheothersphere?mF�G1m�2,wherem�r22�2m1(m1)(2m1)F�G��2rFr2m��1���2G(2.75�10�12N)(2.6m)2�������(2)(6.67�10�11N�m2�kg2)�0.3733kgor0.37kgtotwosignificantdigitsm2�2m1�(2)(0.3733kg)�0.7466kgor0.75totwosignificantdigits65.TheMoonis3.9�105kmfromEarth’scenterand1.5�108kmfromtheSun’scenter.IfthemassesoftheMoon,Earth,andtheSunare7.3�1022kg,6.0�1024kg,and2.0�1030kg,respectively,findtheratioofthegravitationalforcesexertedbyEarthandtheSunontheMoon.mF�G1m�2�r2�11N�m2/kg2)(6.0�1024kg)(7.3�1022kg)EarthonMoon:F����E�(6.67�10(3.9�108m)2�1.9�1020N�11N�m2/kg2)(2.0�1030kg)(7.3�1022kg)SunonMoon:F����E�(6.67�10(1.5�1011m)2�4.3�1020NFE1.9�1020N1.0Ratiois�������FS4.3�1020N2.3TheSunpullsmorethantwiceashardontheMoonasdoesEarth.66.ToyBoatAforceof40.0Nisrequiredtopulla10.0-kgwoodentoyboatataconstantvelocityacrossasmoothglasssurfaceonEarth.WhatforcewouldberequiredtopullthesamewoodentoyboatacrossthesameglasssurfaceontheplanetJupiter?FF���f���f,wherem�Fmgbisthemassofthetoyboat.NbOnJupiter,thenormalforceisequaltothegravitationalattractionCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.betweenthetoyboatandJupiter,ormmF�b�JN�Gr2JFmmNow���f,soF�b�J�FfJ��FN��Gr2NJPhysics:PrinciplesandProblemsSolutionsManual153
157Chapter7continuedFBut���f,soF�mgfJbmbmJmJ(40.0N)(6.67�10�11N�m2/kg2)(1.90�1027kg)�F���F���������fGmgr2fGgr2(9.80m/s2)(7.15�107m)2bJJ�101N67.Mimas,oneofSaturn’smoons,hasanorbitalradiusof1.87�108mandanorbitalperiodofabout23.0h.UseNewton’sversionofKepler’sthirdlawtofindSaturn’smass.2�4�23T����rGm4�2r3m���GT24�2(1.87�108m)3�����(6.67�10�11N�m2/kg2)(8.28�104s)2�5.6�1026kgLevel368.TheMoonis3.9�108mawayfromEarthandhasaperiodof27.33days.UseNewton’sversionofKepler’sthirdlawtofindthemassofEarth.Comparethismasstothemassfoundinproblem60.2�4�23T����rGm4�2r3m�������2GT4�2(3.9�108m)3������(6.67�10�11N�m2/kg2)��(2.361�106s)2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�6.3�1024kgThemassisconsiderablyclosetothatfoundinproblem60.69.Halley’sCometEvery74years,cometHalleyisvisiblefromEarth.FindtheaveragedistanceofthecometfromtheSuninastronomicalunits(AU).ForEarth,r�1.0AUandT�1.0yr3T2��a������a�rTbb3Ta2374y2rr3���(1.0AU)3�a���b�T�������1.0y��b�18AU70.Areaismeasuredinm2,sotherateatwhichareaissweptoutbyaplanetorsatelliteismeasuredinm2/s.a.HowquicklyisanareasweptoutbyEarthinitsorbitabouttheSun?r�1.50�1011mandT�3.156�107s,in365.25days�1.00y�r2�(1.50�1011m)215m2/s������2.24�10T3.156�107s154SolutionsManualPhysics:PrinciplesandProblems
158Chapter7continuedb.HowquicklyisanareasweptoutbytheMooninitsorbitaboutEarth?Use3.9�108mastheaveragedistancebetweenEarthandtheMoon,and27.33daysastheperiodoftheMoon.�(3.9�108m)211m2/s���2.0�102.36�106s7.2UsingtheLawofUniversalGravitationpages192–193Level171.SatelliteAgeosynchronoussatelliteisonethatappearstoremainoveronespotonEarth,asshowninFigure7-24.Assumethatageosynchronoussatellitehasanorbitalradiusof4.23�107m.SatelliterEarth■Figure7-24(Nottoscale)a.Calculateitsspeedinorbit.Gmv�����Er(6.67�10�11N�m2/kg2)(5.97x1024kg)����������4.23�107m�3.07�103m/sor3.07km/sb.Calculateitsperiod.r3T�2����GmE(4.23�107m)3�2����������(6.67�10�11N�m2/kg2)(5.97�1024kg)�2��1.90��10�8s2�8.66�104sor24.1h72.AsteroidTheasteroidCereshasamassof7�1020kgandaradiusof500km.a.WhatisgonthesurfaceofCeres?Gmg���r2(6.67�10�11N�m2/kg2)(7�1020kg)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.������(500�103m)2�0.2m/s2b.Howmuchwoulda90-kgastronautweighonCeres?F2)�20Ng�mg�(90kg)(0.2m/sPhysics:PrinciplesandProblemsSolutionsManual155
159Chapter7continued73.BookA1.25-kgbookinspacehasaweightof8.35N.Whatisthevalueofthegravitationalfieldatthatlocation?F8.35Ng�������6.68N/kgm1.25kg74.TheMoon’smassis7.34�1022kg,anditis3.8�108mawayfromEarth.Earth’smassis5.97�1024kg.a.CalculatethegravitationalforceofattractionbetweenEarthandtheMoon.mmF�GE�M�r2�11N�m2/kg2)(5.98�1024kg)(7.34�1022kg)�(6.67�10����(3.8�108m)2�2.0�1020Nb.FindEarth’sgravitationalfieldattheMoon.F2.03�1020Ng������0.0028N/kgm7.34�1022kgNotethat2.03�1020Ninsteadof2.0�1020Nisusedtopreventroundofferror.75.Two1.00-kgmasseshavetheircenters1.00mapart.Whatistheforceofattractionbetweenthem?mF�1m�2g�Gr2(6.67�10�11N�m2/kg2)(1.00kg)(1.00kg)������(1.00m)2�6.67�10�11NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Level276.TheradiusofEarthisabout6.38�103km.A7.20�103-NspacecrafttravelsawayfromEarth.WhatistheweightofthespacecraftatthefollowingdistancesfromEarth’ssurface?a.6.38�103kmd�rE�rE�2rETherefore,F�1�originalweight���1��3N)�1.80�103Ng�44(7.20�10b.1.28�104kmd�rE�2rE�3rEF�1��3N)�8.00�102Ng��9(7.20�1077.RocketHowhighdoesarockethavetogoaboveEarth’ssurfacebeforeitsweightishalfofwhatitisonEarth?1F��g�r21Sor����Fg156SolutionsManualPhysics:PrinciplesandProblems
160Chapter7continued1Iftheweightis�,thedistanceis�2�(r2E)orr��2�(6.38�106m)�9.02�106m9.02�106m�6.38�106m�2.64�106m�2.64�103km78.Twosatellitesofequalmassareputintoorbit30.0mapart.Thegravitationalforcebetweenthemis2.0�10�7N.a.Whatisthemassofeachsatellite?mF�G1m�2,m�r21�m2�mFr2(2.0�10�7N)(30.0m)2m����G��������6.67�10�11N�m2�kg2�1.6�103kgb.Whatistheinitialaccelerationgiventoeachsatellitebygravitationalforce?Fnet�maFnet2.0�10�7N�10m/s2a������3�1.3�10m1.6�10kg79.Twolargespheresaresuspendedclosetoeachother.Theircentersare4.0mapart,asshowninFigure7-25.Onesphereweighs9.8�102N.Theotherspherehasaweightof1.96�102N.Whatisthegravitationalforcebetweenthem?4.0m9.8�102N1.96�102N■Figure7-25Fg9.8�102N2kgm����1.0�101�g�9.80m/s2Fg1.96�102N1kgm����2.00�102��g9.80m/s2mF�G1m�2�r2(6.67�10�11N�m2/kg2)(1.0�101kg)(2.00�101kg)�������(4.0m)2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�8.3�10�9NPhysics:PrinciplesandProblemsSolutionsManual157
161Chapter7continued80.SupposethecentersofEarthandtheMoonare3.9�108mapart,andthegravitationalforcebetweenthemisabout1.9�1020N.WhatistheapproximatemassoftheMoon?mmF�GE�M�r2Fr2m��M�GmE(1.9�1020N)(3.9�108m)2������(6.67�10�11N�m/kg2)(5.97�1024kg)�7.3�1022kg81.OnthesurfaceoftheMoon,a91.0-kgphysicsteacherweighsonly145.6N.WhatisthevalueoftheMoon’sgravitationalfieldatitssurface?Fg�mg,Fg145.6NSog�������1.60N/kgm91.0kgLevel382.Themassofanelectronis9.1�10�31kg.Themassofaprotonis1.7�10�27kg.Anelectronandaprotonareabout0.59�10�10mapartinahydrogenatom.Whatgravitationalforceexistsbetweentheprotonandtheelectronofahydrogenatom?mempF�G��2r(6.67�10�11N�m2/kg2)(9.1�10�31kg)(1.7�10�27kg)��������(1.0�10�10m)2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.0�10�47N83.Considertwospherical8.0-kgobjectsthatare5.0mapart.a.Whatisthegravitationalforcebetweenthetwoobjects?mF�G1m�2�r2(6.67�10�11N�m2/kg2)(8.0kg)(8.0kg)������(5.0m)2�1.7�10�10Nb.Whatisthegravitationalforcebetweenthemwhentheyare5.0�101mapart?mF�G1m�2�r2(6.67�10�11N�m2/kg2)(8.0kg)(8.0kg)������(5.0�101m)2�1.7�10�12N158SolutionsManualPhysics:PrinciplesandProblems
162Chapter7continued84.Ifyouweigh637NonEarth’ssurface,howmuchwouldyouweighontheplanetMars?Marshasamassof6.42�1023kgandaradiusof3.40�106m.Fg637Nm�������65.0kgg9.80m/s2mF�G1m�2�r2(6.67�10�11N�m2/kg2)(65.0kg)(6.37�1023kg)�������(3.43�106m)2�235N85.UsingNewton’sversionofKepler’sthirdlawandinformationfromTable7-1onpage173,calculatetheperiodofEarth’sMooniftheorbitalradiusweretwicetheactualvalueof3.9�108m.4�23)T��(rM����Gm��E4�28m3������(7.8�10)������(6.67�10�11N�m2/kg2)(5.979�1024kg)�����6.85�106sor79days86.Findthevalueofg,accelerationduetogravity,inthefollowingsituations.a.Earth’smassistripleitsactualvalue,butitsradiusremainsthesame.Gmg���E�9.80m/s2(r2E)2m2)�19.6m/s2E→2g�2(9.80m/sb.Earth’sradiusistripled,butitsmassremainsthesame.Gmg���E�9.80m/s2(r2E)g9.80m/s222r���E→4��42.45m/sc.BoththemassandradiusofEartharedoubled.Gmg��E�(r2E)2g2(9.80m/s2)2m���2Eand2rE→4��44.90m/s87.AstronautWhatwouldbethestrengthofEarth’sgravitationalfieldatapointwherean80.0-kgastronautwouldexperiencea25.0percentreductioninweight?F2)�784Ng�mg�(80.0kg)(9.80m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Fg,reduced�(784N)(0.750)�588NFg,reduced588N2g������7.35m/sreduced�m80.0kgPhysics:PrinciplesandProblemsSolutionsManual159
163Chapter7continuedMixedReviewpages193–194Level188.UsetheinformationforEarthinTable7-1onpage173tocalculatethemassoftheSun,usingNewton’sversionofKepler’sthirdlaw.2�4�23,T���rGm2�4�23andsomT���rG4�2r3m������2GT4�2(1.50�1011m)3������6.67�10�11N�m2/kg2��(3.156�107s)2�2.01�1030kg89.Earth’sgravitationalfieldis7.83N/kgatthealtitudeofthespaceshuttle.Atthisaltitude,whatisthesizeoftheforceofattractionbetweenastudentwithamassof45.0kgandEarth?Fg���mF�mg�(45.0kg)(7.83N/kg)�352N90.UsethedatafromTable7-1onpage173tofindthespeedandperiodofasatellitethatorbitsMars175kmaboveitssurface.r�r6m�0.175�106mM�175km�3.40�106m�3.58�10Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.GMv����Mr(6.67�10�11N�m2/kg2)(6.42�1023kg)����������3.58�106m�3.46�103m/sr3T�2����GMM(3.58�106m)3�2����������(6.67�10�11N�m2/kg2)(6.42�1023kg)�6.45�103sor1.79h160SolutionsManualPhysics:PrinciplesandProblems
164Chapter7continuedLevel291.SatelliteAsatelliteisplacedinorbit,asshowninFigure7-26,witharadiusthatishalftheradiusoftheMoon’sorbit.FindtheperiodofthesatelliteinunitsoftheperiodoftheMoon.MoonrMEarth1��rM2Satellite■Figure7-26T2r3���s����s��TrMMr30.50r3So,T�s�T��MT2s����r��M����r��M�MM��0.125�T�2M�0.35TM92.CannonballTheMoon’smassis7.3�1022kganditsradiusis1785km.IfNewton’sthoughtexperimentoffiringacannonballfromahighmountainwereattemptedontheMoon,howfastwouldthecannonballhavetobefired?Howlongwouldittakethecannonballtoreturntothecannon?Gmv����r(6.67�10�11N�m2/kg2)(7.3�1022kg)����������1.785�106m�1.7�103m/sr3T�2����Gm(1.785�106m)3�2����������(6.67�10�11N�m2/kg2)(7.3�1022kg)�6.8�103s93.TheperiodoftheMoonisonemonth.AnswerthefollowingquestionsassumingthatthemassofEarthisdoubled.a.WhatwouldtheperiodoftheMoonbe?Expressyourresultsinmonths.r3T�2��Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��GmSo,ifEarth’smassweredoubled,buttheradiusremainedthesame,1thentheperiodwouldbereducedbyafactorof�,or0.707months.�2�Physics:PrinciplesandProblemsSolutionsManual161
165Chapter7continuedb.Wherewouldasatellitewithanorbitalperiodofonemonthbelocated?T2r3�����2�GmT2r3����(Gm)2�1Thus,r3wouldbedoubled,orrwouldbeincreasedby2�3�1.26timesthepresentradiusoftheMoon.c.HowwouldthelengthofayearonEarthbeaffected?ThelengthofayearonEarthwouldnotbeaffected.ItdoesnotdependonEarth’smass.Level394.HowfastwouldaplanetofEarth’smassandsizehavetospinsothatanobjectattheequatorwouldbeweightless?Givetheperiodofrotationoftheplanetinminutes.Thecentripetalaccelerationmustequaltheaccelerationduetogravitysothatthesurfaceoftheplanetwouldnothavetosupplyanyforce(otherwiseknownasweight).mv2mEm��G��rr2GmEv�����r2�r2�r2�rBut,v���,soT���TvGmE����r3rCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�2�����GmE(6.38�106m)3�2����������(6.67�10�11N�m2/kg2)(5.97�1024kg)�5.07�103s�84.5min95.CarRacesSupposethataMartianbasehasbeenestablishedandcarracesarebeingconsidered.Aflat,circularracetrackhasbeenbuiltfortherace.Ifacarcanachievespeedsofupto12m/s,whatisthesmallestradiusofatrackforwhichthecoefficientoffrictionis0.50?Theforcethatcausesthecentripetalaccelerationisthestaticfrictionforce:Fstatic�smgv2Thecentripetalaccelerationisa�c�rmv2So,��rsmgv2Thus,r���gsGmNotethatg���(r2planet)162SolutionsManualPhysics:PrinciplesandProblems
166Chapter7continuedTofindgonMars,thefollowingcalculationisused.m23kg,andR6mMars�6.37�10Mars�3.43�10So,g2Mars�3.61m/s(12m/s)2Therefore,R��2)(0.50)(3.61m/sR8.0�101m96.Apollo11OnJuly19,1969,Apollo11’srevolutionaroundtheMoonwasadjustedtoanaverageorbitof111km.TheradiusoftheMoonis1785km,andthemassoftheMoonis7.3�1022kg.a.HowmanyminutesdidApollo11taketoorbittheMoononce?r3m�111�103morbit�1785�10r3T�2����Gm(1896�103m)3�2����������(6.67�10�11N�m2/kg2)(7.3�1022kg)�7.4�103s�1.2�102minb.AtwhatvelocitydidApollo11orbittheMoon?Gmv�����rorbit(6.67�10�11N�m2/kg2)(7.3�1022kg)����������1896�103m�1.6�103m/sThinkingCriticallypage19497.AnalyzeandConcludeSomepeoplesaythatthetidesonEartharecausedbythepulloftheMoon.Isthisstatementtrue?a.DeterminetheforcesthattheMoonandtheSunexertonamass,m,ofwateronEarth.YouranswerwillbeintermsofmwithunitsofN.�11N�m2/kg2(1.99�1030kg)(m)FS,m�6.67�10�����(1.50�1011m)2�(5.90�10�3N)m�11N�m2/kg2(7.36�1022kg)(m)FM,m�6.67�10�����(3.80�108m)2�(3.40�10�5N)mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Whichcelestialbody,theSunortheMoon,hasagreaterpullonthewatersofEarth?TheSunpullsapproximately100timesstrongeronthewatersofEarth.Physics:PrinciplesandProblemsSolutionsManual163
167Chapter7continuedc.DeterminethedifferenceinforceexertedbytheMoononthewateratthenearsurfaceandthewateratthefarsurface(ontheoppositeside)ofEarth,asillustratedinFigure7-27.Again,youranswerwillbeintermsofmwithunitsofN.FartidalbulgeNeartidalbulgeEarthMoon■Figure7-27(Nottoscale)F�11N�m2�kg2)(7.36�1022kg)(m)m,mA�Fm,mB�(6.67�1011�����(3.80�108m�6.37�106m)2�����(3.80�108m�6.37�106m)2��(2.28�10�6N)md.DeterminethedifferenceinforceexertedbytheSunonwateratthenearsurfaceandonwateratthefarsurface(ontheoppositeside)ofEarth.F�11N�m2�kg2)(1.99�1030kg)(m)S,mA�FS,mB�(6.67�1011�����(1.50�1011m�6.37�106m)2����(1.50�1011m�6.37�106m)2��(1.00�10�6N)me.WhichcelestialbodyhasagreaterdifferenceinpullfromonesideofEarthtoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.theother?theMoonf.WhyisthestatementthatthetidesresultfromthepulloftheMoonmisleading?MakeacorrectstatementtoexplainhowtheMooncausestidesonEarth.ThetidesareprimarilyduetothedifferencebetweenthepulloftheMoononEarth’snearsideandEarth’sfarside.98.MakeandUseGraphsUseNewton’slawofuniversalgravitationtofindanequationwherexisequaltoanobject’sdistancefromEarth’scenter,andyisitsaccelerationduetogravity.Useagraphingcalculatortographthisequation,using6400–6600kmastherangeforxand9–10m/s2astherangefory.Theequationshouldbeoftheformy�c(1/x2).Tracealongthisgraphandfindyforthefollowinglocations.a.atsealevel,6400kmc�(Gm6m2/km2)�4.0�108unitsE)(10acc�9.77m/s2b.ontopofMt.Everest,6410km9.74m/s2164SolutionsManualPhysics:PrinciplesandProblems
168Chapter7continuedc.inatypicalsatelliteorbit,6500km9.47m/s2d.inamuchhigherorbit,6600km9.18m/s2WritinginPhysicspage19499.ResearchanddescribethehistoricaldevelopmentofthemeasurementofthedistancebetweentheSunandEarth.OneoftheearliestcrudemeasurementswasmadebyJamesBradleyin1732.TheanswersalsoshoulddiscussmeasurementsofthetransitsofVenusdoneinthe1690s.100.Explorethediscoveryofplanetsaroundotherstars.Whatmethodsdidtheastronomersuse?Whatmeasurementsdidtheytake?HowdidtheyuseKepler’sthirdlaw?Astronomersmeasurethestar’stinyvelocityduetothegravitationalforceexertedonitbyamassiveplanet.ThevelocityiscalculatedbymeasuringtheDopplershiftofthestar’slightthatresultsfromthatmotion.Thevelocityoscillatesbackandforthastheplanetsorbitthestar,allowingcalculationoftheplanet’speriod.Fromthesizeofthevelocitytheycanestimatetheplanet’sdistanceandmass.BycomparingthedistancesandperiodsofplanetsinsolarsystemswithmultipleplanetsandusingKepler’sthirdlaw,astronomerscanbetterseparatethedistancesandmassesofstarsandplanets.CumulativeReviewpage194101.AirplanesAjetairplanetookofffromPittsburghat2:20P.M.andlandedinWashington,DC,at3:15P.M.onthesameday.Ifthejet’saveragespeedwhileintheairwas441.0km/h,whatisthedistancebetweenthecities?(Chapter2)�t�55min�0.917h�d�v����t�d�v��t�(441.0km/h)(0.917h)�404km102.CarolynwantstoknowhowmuchherbrotherJaredweighs.Heagreestostandonascaleforher,butonlyiftheyareridinginanelevator.Ifhestepsonthescalewhiletheelevatorisacceleratingupwardat1.75m/s2andthescalereadsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.716N,whatisJared’susualweightonEarth?(Chapter4)IdentifyJaredasthesystemandupwardaspositive.Fnet�FscaleonJared�FEarth’smassonJared�maPhysics:PrinciplesandProblemsSolutionsManual165
169Chapter7continuedF���Earth’smassonJaredFscaleonJared�FEarth’smassonJared���gaa�FEarth’smassonJared�1��g��FscaleonJaredFEarth’smassonJared�a�1��g��716N�1.75m/s2�1��9.80�m/s2��608N103.PotatoBugA1.0-gpotatobugiswalkingaroundtheouterrimofanupside-downflyingdisk.Ifthediskhasadiameterof17.2cmandthebugmovesatarateof0.63cm/s,whatisthecentripetalforceactingonthebug?Whatagentprovidesthisforce?(Chapter6)mv2(0.0010kg)(0.0063cm)2F�����7N,c��r0.086m�5.0�10providedbythefrictionalforcebetweenthebugandtheflyingdiskChallengeProblempage176AstronomershavedetectedthreeplanetsthatorbitthestarUpsilonAndromedae.PlanetBhasanaverageorbitalradiusof0.059AUandaperiodof4.6170days.PlanetChasanaverageorbitalradiusof0.829AUandaperiodof241.5days.PlanetDhasanaverageorbitalradiusof2.53AUandaperiodof1284days.(DistancesaregiveninCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.astronomicalunits(AU)—Earth’saveragedistancefromtheSun.ThedistancefromEarthtotheSunis1.00AU.)DBrDrBCrCUpsilonAndromedae1.DotheseplanetsobeyKepler’sthirdlaw?r3Testbycalculatingthefollowingratio��.T2r3(0.059AU)3ForplanetB,�B����9.6�10�6AU3/days2T�2(4.6170days)2B166SolutionsManualPhysics:PrinciplesandProblems
170Chapter7continuedr3(0.829AU)3ForplanetC,�C����9.77�10�6AU3/days2T�2(241.5days)2Cr3(2.53AU)3ForplanetD,�D����9.82�10�6AU3/days2T�2(1284days)2DThesevaluesarequiteclose,soKepler’sthirdlawisobeyed.2.FindthemassofthestarUpsilonAndromedaeinunitsoftheSun’smass.r3Gmcentralbody�����T24�2r3(1.000AU)33/y2FortheEarth-Sunsystem,������1.000AUT2(1.000y)2FortheplanetC-Upsilonsystem,r3���9.77�10�6AU3/days2T2�(9.77�10�6AU3/days2)(365days/y)2�1.30AU3/y2Gm��star4�2Theratioofthetwoshowsthestar’sslightlyheaviermasstobe1.30thatoftheSun.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual167
171
172CHAPTER8RotationalMotionBecausetheradiusofthewheelisPracticeProblemsreducedfrom35.4cmto24cm,the8.1DescribingRotationalangularaccelerationwillbeMotionincreased.pages197–200�21�5.23rad/spage200a21.85m/s2����1.Whatistheangulardisplacementofeachof2��r0.24mthefollowinghandsofaclockin1h?State2�7.7rad/syouranswerinthreesignificantdigits.a.thesecondhand4.Youwanttoreplacethetiresonyourcar���(60)(�2�rad)withtiresthathavealargerdiameter.Afteryouchangethetires,fortripsatthesame��120�rador�377radspeedandoverthesamedistance,howwillb.theminutehandtheangularvelocityandnumberofrevolu-����2�rador�6.28radtionschange?c.thehourhandvBecause���,ifrisincreased,�will1r������(�2�rad)decrease.Thenumberofrevolutions12��willalsodecrease.��rador0.524rad62.Ifatruckhasalinearaccelerationof1.85m/s2andthewheelshaveanangularSectionReviewaccelerationof5.23rad/s2,whatisthe8.1DescribingRotationaldiameterofthetruck’swheels?Motionr��a�pages197–200�page2001.85m/s2���5.AngularDisplacementAmovielasts2h.5.23rad/s2Duringthattime,whatistheangulardis-�0.354mplacementofeachofthefollowing?Thus,thediameteris0.707m.a.thehourhand1��3.Thetruckinthepreviousproblemistowing������(�2�rad)��rad63atrailerwithwheelsthathaveadiameterofb.theminutehand48cm.���(2)(�2�rad)��4�rada.Howdoesthelinearaccelerationofthetrailercomparewiththatofthetruck?6.AngularVelocityTheMoonrotatesThechangesinvelocityaretheonceonitsaxisin27.3days.ItsradiusisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.same,sothelinearaccelerations6m.1.74�10arethesame.b.Howdotheangularaccelerationsofthewheelsofthetrailerandthewheelsofthetruckcompare?Physics:PrinciplesandProblemsSolutionsManual169
173Chapter8continueda.WhatistheperiodoftheMoon’srota-9.AngularAccelerationInthespincycletioninseconds?ofaclotheswasher,thedrumturnsatperiod�(27.3day)(24h/day)635rev/min.Ifthelidofthewasheris(3600s/h)opened,themotoristurnedoff.Ifthedrumrequires8.0stoslowtoastop,what�2.36�106sistheangularaccelerationofthedrum?b.WhatisthefrequencyoftheMoon’s�i�635rpm�66.53rad/srotationinrad/s?�1f�0.0,so����66.5rad/s���period���66.5rad/s2and��������8.3rad/s1�t8.0s���rev/s,or2.36�10610.CriticalThinkingACD-ROMhasaspiral2.66�10�6rad/strackthatstarts2.7cmfromthecenterofc.Whatisthelinearspeedofarockonthediskandends5.5cmfromthecenter.theMoon’sequatordueonlytotheThediskdrivemustturnthedisksothatMoon’srotationthelinearvelocityofthetrackisaconstant1.4m/s.Findthefollowing.v�r�a.theangularvelocityofthedisk(inrad/s�(1.74�106m)(2.66�10�6rad/s)andrev/min)forthestartofthetrack�4.63m/sv���d.ComparethisspeedwiththespeedofarpersononEarth’sequatorduetoEarth’s1.4m/s��rotation.0.027mThespeedonEarth’sequatoris�52rad/sor5.0�102rev/min464m/s,orabout100timesfaster.b.thedisk’sangularvelocityattheendofthetrack7.AngularDisplacementTheballinacom-vputermouseis2.0cmindiameter.Ifyou���Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.rmovethemouse12cm,whatistheangulardisplacementoftheball?1.4m/s��0.055md�r��25rad/sor2.4�102rev/mind12cmso������12radr1.0cmc.thedisk’sangularaccelerationifthediskisplayedfor76min8.AngularDisplacementDoallpartsoftheminutehandonawatchhavethesame���f��i�����angulardisplacement?Dotheymovethe�t�tsamelineardistance?Explain.�25rad/s�52rad/s����angulardisplacement—yes;lineardis-(76min)(60s/min)tance—no,becauselineardistanceisa��5.9�10�3rad/s2functionoftheradius170SolutionsManualPhysics:PrinciplesandProblems
174Chapter8continuedPracticeProblems��Frsin��mgrsin�8.2RotationalDynamics�(65kg)(9.80m/s2)(0.18m)(sin55°)pages201–210�94N�mpage20311.ConsiderthewrenchinExampleProblem15.Ifthepedalinproblem14ishorizontal,1.Whatforceisneededifitisappliedtohowmuchtorquewouldyouexert?Howthewrenchatapointperpendiculartothemuchtorquewouldyouexertwhenthewrench?pedalisvertical?��Frsin�Horizontal��90.0°�soF��rsin�so��Frsin��mgrsin�35N�m���(0.25m)(sin90.0°)�(65kg)(9.80m/s2)(0.18m)2N(sin90.0°)�1.4�10�1.1�102N�m12.Ifatorqueof55.0N�misrequiredandtheVertical�=0.0°largestforcethatcanbeexertedbyyouisSo��Frsin�135N,whatisthelengthoftheleverarm�mgrsin�thatmustbeused?�(65kg)(9.80m/s2)(0.18m)Fortheshortestpossibleleverarm,��(sin0.0°)90.0°.�0.0N�m��Frsin��sor��Fsin�page20555.0N�m16.Ashok,whosemassis43kg,sits1.8m���(135N)(sin90.0°)fromthecenterofaseesaw.Steve,whose�0.407mmassis52kg,wantstobalanceAshok.Howfarfromthecenteroftheseesaw13.Youhavea0.234-m-longwrench.AjobshouldStevesit?requiresatorqueof32.4N�m,andyoucanFexertaforceof232N.WhatisthesmallestArA�FSrSangle,withrespecttothevertical,atwhichFArAsor�theforcecanbeexerted?S�FS��Frsin�mAgrA���1�mSgso��sin���Frm��ArA�sin�1����32.4N�mmS(232N)(0.234m)(43kg)(1.8m)�36.6°���52kg�1.5m14.Youstandonthepedalofabicycle.IfyouCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.haveamassof65kg,thepedalmakesan17.Abicycle-chainwheelhasaradiusofangleof35°abovethehorizontal,andthe7.70cm.Ifthechainexertsa35.0-Nforcepedalis18cmfromthecenterofthechainonthewheelintheclockwisedirection,ring,howmuchtorquewouldyouexert?whattorqueisneededtokeepthewheelTheanglebetweentheforceandthefromturning?radiusis90°�35°�55°.Physics:PrinciplesandProblemsSolutionsManual171
175Chapter8continued�chain�Fgr�(�35.0N)(0.0770m)��2.70N�mThus,atorqueof�2.70N�mmustbeexertedtobalancethistorque.18.Twobasketsoffruithangfromstringsgoingaround4.5cm1.1cmpulleysofdifferentdiameters,asshowninFigure8-6.WhatisthemassofbasketA?�1��2F1r1�F2r2m1gr1�m2gr2mm�2r21�r1(0.23kg)(1.1cm)A����4.5cm�0.056kg0.23kg■Figure8-619.Supposetheradiusofthelargerpulleyinproblem18wasincreasedto6.0cm.WhatisthemassofbasketAnow?mm�2r21�r1(0.23kg)(1.1cm)����6.0cm�0.042kg20.Abicyclist,ofmass65.0kg,standsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.45.0°onthepedalofabicycle.Thecrank,whichis0.170mlong,makesa45.0°anglewiththevertical,asshowninFigure8-7.Thecrankis9.70cmattachedtothechainwheel,whichhasaradiusof9.70cm.Whatforce0.170mmustthechainexerttokeepthewheelfromturning?�cr���ch■Figure8-7Fcrrcrsin���Fchrch�FsoF��crrcrsin�ch�rch�mgr���crsin�rch�(65.0kg)(9.80m/s2)(0.170m)(sin45.0°)������0.097m�789N172SolutionsManualPhysics:PrinciplesandProblems
176Chapter8continuedpage20824.Eachsphereinthepreviousproblemhasa21.Twochildrenofequalmassessit0.3mmassof0.10kg.Thedistancebetweenfromthecenterofaseesaw.AssumingthatspheresAandCis0.20m.Findthemomenttheirmassesaremuchgreaterthanthatofofinertiainthefollowinginstances:rotationtheseesaw,byhowmuchisthemomentofaboutsphereA,rotationaboutsphereC.inertiaincreasedwhentheysit0.6mfromAboutsphereA:thecenter?I�mr2�m(2r)2Forthemassofthetwochildren,I�mr2�mr2�2mr2.�5mr2Whenrisdoubled,Iismultipliedbya�(5)(0.10kg)(0.20m)2factorof4.�0.020kg�m222.SupposetherearetwoballswithequalAboutsphereC:diametersandmasses.Oneissolid,andtheI�mr2�mr2otherishollow,withallitsmassdistributedatitssurface.Arethemomentsofinertiaof�2mr2theballsequal?Ifnot,whichisgreater?�(2)(0.10kg)(0.20m)2Themoreofthemassthatislocatedfar2�0.0080kg�mfromthecenter,thegreaterthemomentofinertia.Thus,thehollowballhasagreatervalueofI.page21025.ConsiderthewheelinExampleProblem4.23.Figure8-9showsthreemassivespheresonIftheforceonthestrapweretwiceasgreat,arodofverysmallmass.Considerthewhatwouldbethespeedofrotationofthemomentofinertiaofthesystem,firstwhenwheelafter15s?itisrotatedaboutsphereA,andthenwhenTorqueisnowtwiceasgreat.Theangu-itisrotatedaboutsphereC.Arethelaraccelerationisalsotwiceasgreat,momentsofinertiathesameordifferent?sothechangeinangularvelocityisExplain.Ifthemomentsofinertiaaretwiceasgreat.Thus,thefinalangulardifferent,inwhichcaseisthemomentofvelocityis32�rad/s,or16rev/s.inertiagreater?AC26.Asolidwheelacceleratesat3.25rad/s2whenaforceof4.5Nexertsatorqueonit.Ifthewheelisreplacedbyawheelwithallofitsmassontherim,themomentofiner-tiaisgivenbyI�mr2.Ifthesameangular■Figure8-9velocityweredesired,whatforcewouldThemomentsofinertiaaredifferent.Ifhavetobeexertedonthestrap?thespacingbetweenspheresisrandTheangularaccelerationhasnoteachspherehasmassm,thenrotationchanged,butthemomentofinertiaisaboutsphereAistwiceasgreat.Therefore,thetorqueI�mr2�m(2r)2�5mr2.mustbetwiceasgreat.Theradiusofthewheelisthesame,sotheforceRotationaboutsphereCisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mustbetwiceasgreat,or9.0N.I�mr2�mr2�2mr2.ThemomentofinertiaisgreaterwhenrotatingaroundsphereA.Physics:PrinciplesandProblemsSolutionsManual173
177Chapter8continued27.Abicyclewheelcanbeacceleratedeitherbypullingonthechainthatisonthegearorbypullingonastringwrappedaroundthetire.Thewheel’sradiusis0.38m,whiletheradiusofthegearis0.14m.Ifyouobtainedtheneededaccelerationwithaforceof15Nonthechain,whatforcewouldyouneedtoexertonthestring?Thetorqueonthewheekcomesfromeitherthechainorthestring.�chain�Iwheel�wheel�wheel�Iwheel�wheelThus,�chain��wheelFchainrgear�FstringrwheelFchainrgearF��string�rwheel(15N)(0.14m)���0.38m�5.5N28.Thebicyclewheelinproblem27isusedwithasmallergearwhoseradiusis0.11m.Thewheelcanbeacceleratedeitherbypullingonthechainthatisonthegearorbypullingstringthatiswrappedaroundthetire.Ifyouobtainedtheneededaccelerationwithaforceof15Nonthechain,whatforcewouldyouneedtoexertonthestring?FchainrgearF��string�rwheel(15N)(0.11m)���0.38mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�4.3N29.Adiskwithamomentofinertiaof0.26kg�m2isattachedtoasmallerdiskmountedonthesameaxle.Thesmallerdiskhasadiameterof0.180mandamassof2.5kg.Astrapiswrappedaroundthesmallerdisk,asshowninFigure8-10.Findtheforceneededtogivethissystemanangularaccelerationof2.57rad/s2.F�Fr�����III�soF��r(I�small�Ilarge)■Figure8-10���r��1�m2�I�2smallrsmalllarge����r���1��2�0.26kg�m22)2(2.5kg)(0.090m)�(2.57rad/s�����0.090m�7.7N174SolutionsManualPhysics:PrinciplesandProblems
178Chapter8continued33.MomentofInertiaRefertoTable8-2onSectionReviewpage206andrankthemomentsofinertia8.2RotationalDynamicsfromleasttogreatestofthefollowingpages201–210objects:asphere,awheelwithalmostallofitsmassattherim,andasoliddisk.Allpage210haveequalmassesanddiameters.Explain30.TorqueVijeshentersarevolvingdoorthattheadvantageofusingtheonewiththeisnotmoving.Explainwhereandhowleastmomentofinertia.Vijeshshouldpushtoproduceatorquewiththeleastamountofforce.fromleasttogreatest:sphere��2mr2�,5Toproduceatorquewiththeleastsoliddisk�1mr2,wheel(mr2)force,youshouldpushasclosetothe��2edgeaspossibleandatrightanglestoThelessthemomentofinertia,thelessthedoor.torqueneededtogiveanobjectthesameangularacceleration.31.LeverArmYoutrytoopenadoor,butyouareunabletopushatarightangletothe34.Newton’sSecondLawforRotationaldoor.So,youpushthedooratanangleofMotionAropeiswrappedaroundapulley55°fromtheperpendicular.Howmuchandpulledwithaforceof13.0N.Thepul-harderwouldyouhavetopushtoopentheley’sradiusis0.150m.Thepulley’srota-doorjustasfastasifyouweretopushitattionalspeedgoesfrom0.0to14.0rev/min90°?in4.50s.WhatisthemomentofinertiaofTheanglebetweentheforceandthethepulley?radiusis35°.Torqueis��Frsin�.�Becausesin90°�1,andsin35°�0.57,I����youwouldhavetoincreasetheFr1��forcebyaratioof��1.75toobtain��0.57��thesametorque.�tFr�t��32.NetTorqueTwopeoplearepullingon�f��iropeswrappedaroundtheedgeofalarge(13.0N)(0.150m)(4.50s)wheel.Thewheelhasamassof12kganda����revrev2�radmin�14.0�m�in�0.0�m�in���re�v���60�s�diameterof2.4m.Onepersonpullsinaclockwisedirectionwitha43-Nforce,while2�5.99kg�mtheotherpullsinacounterclockwisedirec-tionwitha67-Nforce.Whatisthenet35.CriticalThinkingAballonanextremelytorqueonthewheel?low-friction,tiltedsurface,willslidedown-�net��1��2hillwithoutrotating.Ifthesurfaceisrough,however,theballwillroll.Explainwhy,�F1r�F2rusingafree-bodydiagram.1�(F�1�F2)�2d�1�(�43N�67N)���(2.4m)2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�29N�mPhysics:PrinciplesandProblemsSolutionsManual175
179Chapter8continuedTorque:��Frsin�.Theforceisdueto1.92mfriction,andthetorquecausestheball0.30m0.66m0.51m0.45mtorotateclockwise.Ifthesurfaceisfric-tion-free,thenthereisnoforceparalleltothesurface,notorque,andthusnorotation.Remember,forcesactingonthepivotpoint(thecenteroftheball)ABareignored.■Figure8-15Extremelylow-frictionRougha.Whatarethetorquesactingonthesurfacesurfaceladder?FnormalFnormalclockwise:�A�FArA��Ffriction��FA(0.96m–0.30m)rrFfriction��(0.66m)FASurfaceSurfacecounterclockwise:FgFg�B�FBrB�FB(0.96m�0.45m)PracticeProblems�(0.51m)FB8.3Equilibriumb.Writetheequationforrotationalequi-pages211–217librium.page215�net��A��B�036.Whatwouldbetheforcesexertedbytheso�twosawhorsesiftheladderinExampleB���AProblem5hadamassof11.4kg?(0.51m)FB��(�(0.66m)FA)Becausenodistanceshavechanged,(0.51m)FB�(0.66m)FAtheequationsarestillvalid:Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.SolvetheequationforFrAintermsofFg.gmgFB��rFBg�FA�FB(0.30m)(11.4kg)(9.80m/s2)thus,FF����A�Fg�FBB��1.05m32N(0.66m)FrAg�F��FA�mg�1���g�0.51mrBFg�(11.4kg)(9.80m/s2)0.30m�orF���1�1.05m�A�0.66m1���0.51m�8.0�101Nma���0.66m37.A7.3-kgladder,1.92mlong,restsontwo1���0.51msawhorses,asshowninFigure8-15.(7.3kg)(9.80m/s2)SawhorseA,ontheleft,islocated0.30m����0.66m1���fromtheend,andsawhorseB,ontheright,0.51mislocated0.45mfromtheotherend.�31NChoosetheaxisofrotationtobethecenterd.Howwouldtheforcesexertedbytheofmassoftheladder.twosawhorseschangeifAweremovedverycloseto,butnotdirectlyunder,thecenterofmass?176SolutionsManualPhysics:PrinciplesandProblems
180Chapter8continuedFAwouldbecomegreater,andFB�g(2mdiverg�mboard)wouldbeless.�(9.80m/s2)38.A4.5-m-longwoodenplankwitha24-kg(2(85kg)�14kg)massissupportedintwoplaces.Onesup-�1.8�103Nportisdirectlyunderthecenteroftheboard,andtheotherisatoneend.Whataretheforcesexertedbythetwosupports?SectionReviewPickthecenterofmassoftheboardasthepivot.Theunsupportedendexerts8.3Equilibriumnotorque,sothesupportedenddoespages211–217nothavetoexertanytorque.Therefore,page217alltheforceisexertedbythecenter40.CenterofMassCanthecenterofmassofsupport.Thatforceisequaltotheanobjectbelocatedinanareawheretheweightoftheboard:objecthasnomass?Explain.F2)Yes,anobjectmovesasifallitsmasscenter�Fg�(24kg)(9.80m/s�2.4�102Nisconcentratedatthecenterofmass.ThereisnothinginthedefinitionthatFend�0Nrequiresanyoralloftheobject’smass39.A85-kgdiverwalkstotheendofadivingtobeatthatlocation.board.Theboard,whichis3.5mlongwith41.StabilityofanObjectWhyisamodifiedamassof14kg,issupportedatthecentervehiclewithitsbodyraisedhighonrisersofmassoftheboardandatoneend.Whatlessstablethanasimilarvehiclewithitsaretheforcesonthetwosupports?bodyatnormalheight?ChoosethecenterofmassoftheboardThecenterofmassofthevehiclewillasthepivot.TheforceofEarth’sgravityberaised,butthesizeofitsbasewillontheboardisexertedtotallyonthenotbeincreased.Therefore,itneedstosupportunderthecenterofmass.betippedatasmallerangletogetthe�end���divercenterofmassoutsidethebaseoftheFendrend��Fdiverrdivervehicle.�FThus,F��diverrdiver42.ConditionsforEquilibriumGiveanend�rendexampleofanobjectforeachofthefollow-�mdivergrdiveringconditions.���renda.rotationalequilibrium,butnottransla-�(85kg)(9.80m/s2)(1.75m)tionalequilibrium�����1.75mabookthatisdroppedsoitfalls��8.3�102NwithoutrotatingTofindtheforceonthecentersupport,b.translationalequilibrium,butnotrota-noticethatbecausetheboardisnottionalequilibriummoving,aseesawthatisnotbalancedandFrotatesuntiloneperson’sfeethittheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.end�Fcenter�Fdiver�FggroundThus,Fcenter�Fdiver�Fg�Fend43.CenterofMassWhereisthecenterof�2Fdiver�Fgmassofarollofmaskingtape?�2mdiverg�mboardgItisinthemiddleoftheroll,intheopenspace.Physics:PrinciplesandProblemsSolutionsManual177
181Chapter8continued44.LocatingtheCenterofMassDescribeChapterAssessmenthowyouwouldfindthecenterofmassofthistextbook.ConceptMappingObtainapieceofstringandattachapage222smallweighttoit.Suspendthestring47.Completethefollowingconceptmapusingandtheweightfromonecornerofthethefollowingterms:angularacceleration,book.Drawalinealongthestring.radius,tangentialacceleration,centripetalSuspendthetwofromanothercornerofacceleration.thebook.Again,drawalinealongthestring.ThepointwherethelinescrossAngularAngularvelocityaccelerationisthecenterofmass.Radius45.RotatingFramesofReferenceApennyisCentripetalTangentialplacedonarotating,old-fashionedrecordaccelerationaccelerationturntable.Atthehighestspeed,thepennystartsslidingoutward.Whataretheforcesactingonthepenny?MasteringConceptsEarth’smassexertsadownwardforce.page222Theturntable’ssurfaceexertsbothan48.Abicyclewheelrotatesataconstantupwardforcetobalancegravityandan25rev/min.Isitsangularvelocitydecreas-inwardforceduetofrictionthatgivesing,increasing,orconstant?(8.1)thepennyitscentripetalacceleration.Itisconstant.Thereisnooutwardforce.Ifitwerenotforfriction,thepennywouldmoveina49.Atoyrotatesataconstant5rev/min.Isitsstraightline.angularaccelerationpositive,negative,orzero?(8.1)46.CriticalThinkingYouhavelearnedwhyItiszero.thewindsaroundalow-pressureareamoveCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.inacounterclockwisedirection.Wouldthe50.DoallpartsofEarthrotateatthesamerate?windsmoveinthesameoroppositedirec-Explain.(8.1)tioninthesouthernhemisphere?Explain.Yes,becauseallpartsofarigidbodyTheywouldmoveintheoppositedirec-rotateatthesamerate.tion.Windsfromthenorthmovefromtheequator,wherethelinearspeeddue51.Aunicyclewheelrotatesataconstanttorotationishighest,tomid-latitudes,14rev/min.Isthetotalaccelerationofawhereitislower.Thus,thewindsbendpointonthetireinward,outward,tangen-totheeast.Windsfromthesouthblowtial,orzero?(8.1)fromregionswherethelinearspeedisItisinward(centripetal).lowtoregionswhereitishigher;thus,theybendtothewest.Thesetwofac-52.Thinkaboutsomepossiblerotationsoftorsresultinaclockwiserotationyourtextbook.Arethemomentsofinertiaaroundalow-pressurearea.aboutthesethreeaxesthesameordiffer-ent?Explain.(8.2)Theyarealldifferent.Theonewiththemostmass,farthestfromtheaxis,hasthegreatestmomentofinertia.178SolutionsManualPhysics:PrinciplesandProblems
182Chapter8continued53.Torqueisimportantwhentighteningbolts.58.Supposeyoustandflat-footed,thenyouriseWhyisforcenotimportant?(8.2)andbalanceontiptoe.IfyoustandwithAnangularaccelerationmustbepro-yourtoestouchingawall,youcannotducedtotightenabolt.Differentbalanceontiptoe.Explain.(8.3)torquescanbeexertedwithwrenchesYourcenterofmassmustbeabovetheofdifferentlengths.pointofsupport.Butyourcenterofmassisroughlyinthecenterofyour54.Rankthetorquesonthefivedoorsshownbody.Thus,whileyouareonyourtoes,inFigure8-18fromleasttogreatest.Noteabouthalfofyourbodymustbeinfrontthatthemagnitudeofalltheforcesistheofyourtoes,andhalfmustbebehind.Ifsame.(8.2)yourtoesareagainstthewall,nopartofyourbodycanbeinfrontofyourABtoes.59.WhydoesagymnastappeartobefloatingCDonairwhensheraisesherarmsaboveherheadinaleap?(8.3)Shemoveshercenterofmassclosertoherhead.E60.Whyisavehiclewithwheelsthathavea■Figure8-18largediametermorelikelytorolloverthan0�E�D�C�B�Aavehiclewithwheelsthathaveasmallerdiameter?(8.3)55.Explainhowyoucanchangeanobject’sThecenterofmassofthevehiclewithangularfrequency.(8.2)thelargerwheelsislocatedatahigherChangetheamountoftorqueappliedtopoint.Thusitdoesnothavetobetiltedtheobjectorchangethemomentofveryfarbeforeitrollsover.inertia.ApplyingConcepts56.Tobalanceacar’swheel,itisplacedonapages222–223verticalshaftandweightsareaddedto61.Twogearsareincontactandrotating.Onemakethewheelhorizontal.Whyisthisislargerthantheother,asshowninFigureequivalenttomovingthecenterofmass8-19.Comparetheirangularvelocities.Alsountilitisatthecenterofthewheel?(8.3)comparethelinearvelocitiesoftwoteethWhenthewheelisbalancedsoitdoesthatareincontact.nottilt(rotate)inanydirection,thenthereisnonettorqueonit.Thismeansthatthecenterofmassisatthepivotpoint.57.Astuntdrivermaneuversamonstertrucksothatitistravelingononlytwowheels.Whereisthecenterofmassofthetruck?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(8.3)■Figure8-19Itisdirectlyabovethelinebetweenthepointswherethetwowheelsaretouch-ingtheground.Thereisnonettorqueonthetruck,soitismomentarilystable.Physics:PrinciplesandProblemsSolutionsManual179
183Chapter8continuedTheteethhaveidenticallinearveloci-66.BowlingBallWhenabowlingballleavesaties.Becausetheradiiaredifferentbowler’shand,itdoesnotspin.Afterithasvgoneabouthalfthelengthofthelane,how-and���,theangularvelocitiesarerever,itdoesspin.Explainhowitsrotationdifferent.rateincreasedandwhyitdoesnotcontinuetoincrease.62.VideotapeWhenavideotapeisrewound,Itsrotationratecanbeincreasedonlyifwhydoesitwindupfastesttowardstheend?atorqueisappliedtoit.ThefrictionalThemachineturnsthespoolatacon-forceofthealleyontheballprovidesstantangularvelocity.Towardstheend,thisforce.Oncetheballisrollingsothespoolhasthegreatestradius.thatthereisnovelocitydifferenceBecausev�r�,thevelocityofthetapebetweenthesurfaceoftheballandtheisfastestwhentheradiusisgreatest.alley,thenthereisnomorefrictionalforceandthusnomoretorque.63.SpinCycleWhatdoesaspincycleofawashingmachinedo?Explainintermsof67.FlatTireSupposeyourcarhasaflattire.theforcesontheclothesandwater.YougetoutyourtoolsandfindalugwrenchtoremovethenutsofftheboltInthespincycle,thewaterandclothesstuds.Youfinditimpossibletoturntheundergogreatcentripetalaccelerations.nuts.YourfriendsuggestswaysyoumightThedrumcanexertforcesontheproduceenoughtorquetoturnthem.Whatclothes,butwhenthewaterreachesthethreewaysmightyourfriendsuggest?holesinthedrum,noinwardforcecanbeexertedonitanditthereforemovesPutanextensionpipeontheendoftheinastraightline,outofthedrum.wrenchtoincreasetheleverarm,exertyourforceatrightanglestothewrench,64.Howcanyouexperimentallyfindtheorexertagreaterforce,perhapsbymomentofinertiaofanobject?standingontheendofthewrench.Youcanapplyaknowntorqueandmea-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.68.TightropeWalkersTightropewalkerssuretheresultingangularacceleration.oftencarrylongpolesthatsagsothatthe65.BicycleWheelsThreebicyclewheelshaveendsarelowerthanthecenterasshowninmassesthataredistributedinthreedifferentFigure8-20.Howdoessuchapoleincreaseways:mostlyattherim,uniformly,andthetightropewalker’sstability?Hint:mostlyatthehub.ThewheelsallhavetheConsiderbothcenterofmassandmomentofsamemass.Ifequaltorquesareappliedtoinertia.them,whichonewillhavethegreatestangularacceleration?Whichonewillhavetheleast?Themoremassthereisfarfromtheaxis,thegreaterthemomentofinertia.Iftorqueisfixed,thegreaterthemomentofinertia,thelesstheangularacceleration.Thus,thewheelwithmassmostlyatthehubhastheleastmoment■Figure8-20ofinertiaandthegreatestangularacceleration.Thewheelwithmassmostlyneartherimhasthegreatestmomentofinertiaandtheleastangularacceleration.180SolutionsManualPhysics:PrinciplesandProblems
184Chapter8continuedThepoleincreasesmomentofinertiaMasteringProblemsbecauseofitsmassandlength.The8.1DescribingRotationalMotiondroopingendsofthepolebringthepages223–224centerofmassclosertothewire,thusreducingthetorqueonthewalker.TheLevel1increasedmomentofinertiaand72.Awheelisrotatedsothatapointonthedecreasedtorquebothreducetheangu-edgemovesthrough1.50m.Theradiuslaraccelerationifthewalkerbecomesofthewheelis2.50m,asshowninunbalanced.ThewalkercanalsouseFigure8-21.Throughwhatangle(inradi-thepoletoeasilyshiftthecenterofans)isthewheelrotated?massoverthewiretocompensateforinstability.m0.51.50m69.Merry-Go-RoundWhileridingamerry-go-2round,youtossakeytoafriendstanding�ontheground.Foryourfriendtobeabletocatchthekey,shouldyoutossitasecondortwobeforeyoureachthespotwhereyourfriendisstandingorwaituntilyourfriendisdirectlybehindyou?Explain.■Figure8-21Youhaveforwardtangentialvelocity,sod�r�thekeywillleaveyourhandwiththatdso���velocity.Therefore,youshouldtossitrearly.1.50m��2.50m70.Whycanyouignoreforcesthatactonthe�0.600radaxisofrotationofanobjectinstaticequi-libriumwhendeterminingthenettorque?73.TheouteredgeofatrucktirethathasaradiusThetorquecausedbytheseforcesisof45cmhasavelocityof23m/s.Whatisthezerobecausetheleverarmiszero.angularvelocityofthetireinrad/s?v�r�,71.Insolvingproblemsaboutstaticequilibri-vum,whyistheaxisofrotationoftenplaced���ratapointwhereoneormoreforcesareact-23m/singontheobject?���51rad/s0.45mThatmakesthetorquecausedbythat74.Asteeringwheelisrotatedthrough128°,asforceequaltozero,reducingthenum-showninFigure8-22.Itsradiusis22cm.beroftorquesthatmustbecalculated.Howfarwouldapointonthesteeringwheel’sedgemove?22cm128°Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.■Figure8-22Physics:PrinciplesandProblemsSolutionsManual181
185Chapter8continuedd�r�Level278.WashingMachineAwashingmachine’s2�rad�(0.22m)(128°)����0.49mtwospincyclesare328rev/minand542360°rev/min.Thediameterofthedrumis0.43m.75.PropellerApropellerspinsat1880rev/min.a.Whatistheratioofthecentripetalaccel-a.Whatisitsangularvelocityinrad/s?erationsforthefastandslowspincycles?rev2�radminv2���1880��������Recallthata��andv�rw.minrev60sc�rar�2�197rad/s�fast��fastaslowr�2b.Whatistheangulardisplacementoftheslowpropellerin2.50s?(542rev/min)2���2���t(328rev/min)�(197rad/s)(2.50s)�2.73�492radb.Whatistheratioofthelinearvelocityofanobjectatthesurfaceofthedrumfor76.Thepropellerinthepreviousproblemthefastandslowspincycles?slowsfrom475rev/minto187rev/mininv��fast��fastr4.00s.Whatisitsangularacceleration?vslow�slowr��������fast�t�slow���f��i542rev/min�t���328rev/min(187rev/min�475rev/min)2�rad���������1.654.00srev1min����79.Findthemaximumcentripetalacceleration60sintermsofgforthewashingmachinein��7.54rad/s2problem78.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2r1g77.Anautomobilewheelwitha9.00cmac������9.80m/s2radius,asshowninFigure8-23,rotatesat2�rad1min22.50rad/s.Howfastdoesapoint7.00cm��542rev/min�������rev60sfromthecentertravel?0.43m1g���2����29.80m/s�71gLevel380.Alaboratoryultracentrifugeisdesignedtoproduceacentripetalaccelerationof0.35�106gatadistanceof2.50cmfromtheaxis.Whatangularvelocityinrev/minisrequired?■Figure8-23v�r��(7.00cm)(2.50rad/s)�17.5cm/s182SolutionsManualPhysics:PrinciplesandProblems
186Chapter8continueda2r83.Atoyconsistingoftwoballs,each0.45kg,c��attheendsofa0.46-m-long,thin,light-aso�����cweightrodisshowninFigure8-25.Findrthemomentofinertiaofthetoy.The(0.35�106)(9.80m/s2)revmomentofinertiaistobefoundaboutthe�������0.025m���2�radcenteroftherod.60s����0.45kg0.45kg1min�1.1�105rev/min8.2RotationalDynamics0.46mpage224■Figure8-25Level1I�mr281.WrenchAboltistobetightenedwithatorqueof8.0N�m.Ifyouhaveawrench�(0.45kg)(0.23m)2�(0.45kg)(0.23m)2thatis0.35mlong,whatistheleast2�0.048kg�mamountofforceyoumustexert?��Frsin��Level2soF��rsin�84.Abicyclewheelwitharadiusof38cmisgivenanangularaccelerationof2.67rad/s2Fortheleastpossibleforce,theangleis90.0°,thenbyapplyingaforceof0.35Nontheedgeofthewheel.Whatisthewheel’smoment8.0N�mF����ofinertia?(0.35m)(sin90.0°)��23N���I82.WhatisthetorqueonaboltproducedbyaI�����15-Nforceexertedperpendiculartoawrenchthatis25cmlong,asshowninFrsin�����Figure8-24?(0.35N)(0.38m)(sin90.0°)�����F2.67rad/s290°�0.050kg�m225cmLevel385.ToyTopAtoytopconsistsofarodwithadiameterof8.0-mmandadiskofmass0.0125kgandadiameterof3.5cm.Themomentofinertiaoftherodcanbeneglected.Thetopisspunbywrappingastringaroundtherodandpullingitwitha■Figure8-24velocitythatincreasesfromzeroto3.0m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��Frsin�over0.50s.�(15N)(0.25m)(sin90.0°)�3.8N�mPhysics:PrinciplesandProblemsSolutionsManual183
187Chapter8continueda.Whatistheresultingangularvelocityofthetop?v��ff�rrod3.0m/s���1����(0.0080m)2�7.5�102rad/sb.Whatforcewasexertedonthestring?��Frrodsin�and���IThus,Frrodsin���I�IF���rrodsin���12����t���2��mrdisk���rrodsin���mr2���disk2�trrodsin�(�2���f��i)mrdisk2�trrodsin�0.035m2(7.5�102rad/s�0.0rad/s)(0.0125kg)����2�����0.0080m(2)(0.50s)����(sin90.0°)2�0.72NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.8.3Equilibriumpage224Level186.A12.5-kgboard,4.00mlong,isbeingheldupononeendbyAhmed.Hecallsforhelp,andJudiresponds.a.WhatistheleastforcethatJudicouldexerttolifttheboardtothehorizontalposition?Whatpartoftheboardshouldshelifttoexertthisforce?Attheoppositeend,shewillonlylifthalfthemass.Fleast�mg12)����(12.5kg)(9.80m/s2�61.2Nb.WhatisthegreatestforcethatJudicouldexerttolifttheboardtothehorizontalposition?Whatpartoftheboardshouldshelifttoexertthisforce?Attheboard’scenterofmass(middle),shewilllifttheentiremass.Fgreatest�mg�(12.5kg)(9.80m/s2)�122N184SolutionsManualPhysics:PrinciplesandProblems
188Chapter8continuedLevel287.Twopeopleareholdinguptheendsofa4.25-kgwooden6.00kgboardthatis1.75mlong.A6.00-kgboxsitsontheboard,0.50mfromoneend,asshowninFigure8-26.Whatforcesdothetwopeopleexert?Inequilibrium,thesumofallforcesiszeroandthesumofthetorquesaboutanaxisofrotationiszero.1.25m0.50mFleft�Fright�Fboard�Fbox�0■Figure8-26�left��right��board��box�0Wecanchoosetheaxisofrotationatthelocationofoneoftheunknownforces(Fleft)sothattorqueiseliminated,thussimplifyingthecalculations.Fleftrleft�Frightrright�Fboardrboard�Fboxrbox�0Fleftrleft�Frightrright�mboardgrboard�mboxgrbox�02)1.25m�0.50mFleft(0)�Fright(1.25m�0.50m)�(4.25kg)(�9.80m/s����2�(6.00kg)(�9.80m/s2)(1.25m)�0Fright�63NSubstitutingthisintotheforceequation,Fleft�Fright�Fboard�Fbox�0Fleft��Fright�Fboard�Fbox��Fright�mboardg�mboxg��(63N)�(4.25kg)(�9.80m/s2)�(6.00kg)(�9.80m/s2)�37NLevel388.Acar’sspecificationsstatethatitsweightdistributionis53percentonthefronttiresand47percentonthereartires.Thewheelbaseis2.46m.Whereisthecar’scenterofmass?Letthecenterofmassbexfromthefrontofthecar.LettheweightofthecarbeFg.�front��rearFfrontrfront�Frearrrear(0.53Fg)x�(0.47Fg)(2.46m�x)x�1.16mMixedReviewCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pages224–225Level189.Awoodendoorofmass,m,andlength,l,isheldhorizontallybyDanandAjit.Dansuddenlydropshisend.Physics:PrinciplesandProblemsSolutionsManual185
189Chapter8continueda.WhatistheangularaccelerationoftheThen,doorjustafterDanletsgo?�left���bagsThetorqueisduetothegravitation-Fleftrleft��Fbagsrbagsalforce.Theforceatthecenterofmassismg.�FbagsrbagsF���left�rleftThus,���I�(10)(�175N)(0.50m)����Frsin�2.43m����1��2�3.6�102N3mlSubstitutethisintotheforceequation.1mg��2�l�(sin90.0°)F���left�Fright�Fbags�012����mlF3right��Fleft�Fbags��3gl��3.6�102N�10(�175N)2�1.4�102Nb.Istheaccelerationconstant?Explain.No;theanglebetweenthedoorand91.BasketballAbasketballisrolleddownthetheweightischanging,andthere-court.Aregulationbasketballhasadiame-forethetorqueisalsochanging.terof24.1cm,amassof0.60kg,andaThus,theaccelerationchanges.momentofinertiaof5.8�10�3kg�m2.Thebasketball’sinitialvelocityis2.5m/s.90.TopsoilTenbagsoftopsoil,eachweighinga.Whatisitsinitialangularvelocity?175N,areplacedona2.43-m-longsheetofwood.Theyarestacked0.50mfromonev���rendofthesheetofwood,asshowninFigure8-27.Twopeopleliftthesheetof2.5m/s���wood,oneateachend.Ignoringtheweight�1�(0.241m)2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofthewood,howmuchforcemusteachpersonexert?�21rad/sb.Theballrollsatotalof12m.Howmanyrevolutionsdoesitmake?d�r�dso���r12mrev�������12�rad����(0.241m)21.93m�16revc.Whatisitstotalangulardisplacement?0.50md�r�■Figure8-27dInequilibrium,thesumoftheforcesisso���rzeroandthesumofthetorquesiszero.F12mleft�Fright�Fbags�0���1�����(0.241m)left��right��bags�02ChoosethelocationofF�1.0�102radrightastheaxisofrotationtomakethattorquezero.186SolutionsManualPhysics:PrinciplesandProblems
190Chapter8continued92.Thebasketballinthepreviousproblemdstopsrollingaftertraveling12m.v��ta.Ifitsaccelerationwasconstant,what(2.50m)wasitsangularacceleration?���(1.25s)v2�v2�2adfi�2.00m/s�v2soa��ic.Whatistheangularvelocityofthe2dcylinder?a�v2Thus,�����ivr2rd���r�(2.5m/s)2���2.00m/s1��2����(0.241m)(12m)12����(50m)2��2.2rad/s2�8�10�2rad/sb.Whattorquewasactingonitasitwasslowingdown?94.HardDriveAharddriveonamoderncomputerspinsat7200rpm(revolutions��I�perminute).Ifthedriveisdesignedtostart�(5.8�10�3kg�m2)(�2.2rad/s2)fromrestandreachoperatingspeedin1.5s,��1.3�10�2N�mwhatistheangularaccelerationofthedisk?���f��i�����93.Acylinderwitha50mdiameter,asshown�t�tinFigure8-28,isatrestonasurface.A(7200rpm�0rpm)2�rad1minropeiswrappedaroundthecylinderand����1.5s���rev��60s��pulled.Thecylinderrollswithoutslipping.�5.0�102rad/s295.SpeedometersMostspeedometersinauto-mobilesmeasuretheangularvelocityofthetransmissionandconvertittospeed.Howwillincreasingthediameterofthetiresaffectthereadingofthespeedometer?50mBecauseincreasingthediameterdecreasestheangularvelocity,itwillalsodecreasethereadingofthespeedometer.■Figure8-2896.Aboxisdraggedacrossthefloorusingaa.Aftertheropehasbeenpulledadis-ropethatisadistancehabovethefloor.tanceof2.50mataconstantspeed,Thecoefficientoffrictionis0.35.Theboxishowfarhasthecenterofmassofthe0.50mhighand0.25mwide.Findthecylindermoved?forcethatjusttipsthebox.ThecenterofmassisalwaysoverLetMequalthemassofthebox.Thethepointofcontactwiththesurfacecenterofmassoftheboxis0.25mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.forauniformcylinder.Thereforetheabovethefloor.Theboxjusttipswhencenterofmasshasmoved2.50m.thetorquesonitareequal.b.Iftheropewaspulledadistanceof�rope��friction2.50min1.25s,howfastwasthecen-Fterofmassofthecylindermoving?roperrope�FfrictionrfrictionPhysics:PrinciplesandProblemsSolutionsManual187
191Chapter8continuedFThelongerpieceoflumberwouldbeF��frictionrfrictionrope�reasiertokeepfromrotatingbecauseropeithasagreatermomentofinertia.�Mgr���frictionrrope99.SurfboardHarrisandPaulcarryasurf-(0.35)M(9.80m/s2)(0.25m)boardthatis2.43mlongandweighs143N.�����h�0.25mPaulliftsoneendwithaforceof57N.(0.86m2/s2)Ma.WhatforcemustHarrisexert?���h�0.25mFH�Fg�FPNotethatwhenyoupulltheboxattheheightofitscenterofmass,thedenom-�143N�57Ninatorbecomeszero.Thatis,youcan�86Npullwithanyamountofforceandnotb.WhatpartoftheboardshouldHarrislift?tipthebox.ChoosethepointofrotationattheendwherePaullifts.97.Thesecondhandonawatchis12mmlong.Whatisthevelocityofitstip?�H��gv�r�FHrH�Fgrgmin�(0.012m)(�2�rad/min)���60sFgrgr�H�F��1.3�10�3m/sH2.43m(143N)����2Level2���86N98.LumberYoubuya2.44-m-longpieceof�2.0m10cm�10cmlumber.YourfriendbuysapieceofthesamesizeandcutsitintotwoThus,Harrishastolift2.0mfromlengths,each1.22mlong,asshowninPaul’sendoftheboard.Figure8-29.YoueachcarryyourlumberCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.onyourshoulders.100.Asteelbeamthatis6.50mlongweighs325N.Itrestsontwosupports,3.00mapart,withequalamountsofthebeam2.44mextendingfromeachend.Suki,whoweighs575N,standsonthebeaminthecenterandthenwalkstowardoneend.Howclosetotheendcanshecomebeforethebeambeginstotip?1.22mEachsupportis1.75mfromtheendofthebeam.Choosethepointofrotation1.22mtobethesupportattheendcloserto■Figure8-29Suki.Thecenterofmassofthebeama.Whichloadiseasiertolift?Why?is1.50mfromthatsupport.ThebeamThemassesarethesame,sothewilljustbegintotipwhenSuki’sweightsarethesame.Thus,thetorque(�S)equalsthetorqueofthesameupwardforceisrequiredtoliftbeam’scenterofmass(�cm)andtheeachload.entireweightisonthesupportclosesttoSuki.b.Bothyouandyourfriendapplya�torquewithyourhandstokeeptheS��cmlumberfromrotating.WhichloadisFSrS�Fcmrcmeasiertokeepfromrotating?Why?188SolutionsManualPhysics:PrinciplesandProblems
192Chapter8continuedFr�cmrcmS�FS3.00m(325N)����2���575NCable�0.848mThatisSukicanmove0.848mfromAxisofCenterofthesupportor1.75�0.848�0.90mrotationmass25.0°fromtheend.1.05m1.80mThinkingCritically2.10mpages225–226101.ApplyConceptsConsiderapointontheedgeofarotatingwheel.a.Underwhatconditionscanthecen-tripetalaccelerationbezero?when��0.0b.Underwhatconditionscanthetangen-■Figure8-30tial(linear)accelerationbezero?Wecanusetorquestofindtheverticalwhen��0.0component(FTy)ofthetension.Thecounterclockwisetorquesareinequi-c.Canthetangentialaccelerationbelibriumwiththeclockwisetorques.nonzerowhilethecentripetalaccelera-�tioniszero?Explain.ccw��cwWhen��0.0instantaneously,but�cable��pole��banner�isnotzero,�willkeepchanging.FTyrcable�Fpolerpole�Fbannerrbannerd.Canthecentripetalaccelerationbenonzerowhilethetangentialaccelera-Fpolerpole�FbannerrbannerF����tioniszero?Explain.Ty�rcableYes,aslongas�isconstantbutThetotaltension,then,isnotzero.FFTypolerpole�FbannerrbannerF�����T��sin25°r102.ApplyConceptsWhenyouapplythecablesin25°brakesinacar,thefrontenddips.Why?(175N)(1.05m)�(105N)(1.80m)�����(2.10m)sin25°Theroadexertsaforceonthetiresthatbringsthecartorest.Thecenter�420Nofmassisabovetheroad.Therefore,thereisanettorqueonthecar,caus-ingittorotateinthedirectionthatforcesthefrontdown.103.AnalyzeandConcludeAbannerissus-pendedfromahorizontal,pivotedpole,asCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.showninFigure8-30.Thepoleis2.10mlongandweighs175N.Thebanner,whichweighs105N,issuspended1.80mfromthepivotpointoraxisofrotation.Whatisthetensioninthecablesupportingthepole?Physics:PrinciplesandProblemsSolutionsManual189
193Chapter8continued104.AnalyzeandConcludeApivotedlampThetotaltension,then,ispoleisshowninFigure8-31.ThepoleFTyweighs27N,andthelampweighs64N.FT���sin105°Fpolerpole�Flamprlamp����rropesin105°Rope0.44m�y(27N)�����(64N)(0.33m)2����(0.44m)(sin105°)105.0°Axisof�x�64Nrotation105.AnalyzeandConcludeGeraldand0.33mEvelyncarrythefollowingobjectsupa0.44mflightofstairs:alargemirror,adresser,andatelevision.Evelynisatthefrontend,andGeraldisatthebottomend.AssumeLampthatbothEvelynandGeraldexertonlyupwardforces.■Figure8-31a.Drawafree-bodydiagramshowinga.Whatisthetorquecausedbyeachforce?GeraldandEvelynexertingthesame�forceonthemirror.g�Fgrsin�Mirror�(27N)(0.22m)(sin90.0°)�5.9N�mFEFG�rElamp�Flamprsin�cm�(64N)(0.33m)(sin90.0°)rG�21N�mrE�rG�E��GCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Determinethetensionintheropesup-portingthelamppole.FgUsethetorquestofindtheverticalb.Drawafree-bodydiagramshowingcomponent(FTy)ofthetension.TheGeraldexertingmoreforceonthebot-counterclockwisetorquesareintomofthedresser.equilibriumwiththeclockwisetorques.Dresser�FGccw��cw�rope��pole��lampFErEFcmTyrrope�Fpolerpole�FlamprlamprGFrErG�E��Gpolerpole�FlamprlampF���Ty�rropeFg190SolutionsManualPhysics:PrinciplesandProblems
194Chapter8continuedc.WherewouldthecenterofmassoftheCumulativeReviewtelevisionhavetobesothatGeraldpage226carriesalltheweight?108.Twoblocks,oneofmass2.0kgandthedirectlyabovewhereGeraldisotherofmass3.0kg,aretiedtogetherwithliftingamasslessrope.ThisropeisstrungoveraTVmassless,resistance-freepulley.Theblocksarereleasedfromrest.Findthefollowing.(Chapter4)FGcma.thetensionintheropeThetensionontheropeisT�m2g�m2aFgT�m3g�m3aThus,WritinginPhysicsma�����3�m2gpage226m3�m2106.AstronomersknowthatifasatelliteistooSubstituteintothefirstequation.closetoaplanet,itwillbetornapartby2mtidalforces.Thatis,thedifferenceintheT�����2m3gmgravitationalforceonthepartofthesatel-2�m3litenearesttheplanetandthepartfarthest2(2kg)(3kg)2)���(9.80m/sfromtheplanetisstrongerthantheforces2kg�3kgholdingthesatellitetogether.Doresearch�24NontheRochelimitanddeterminehowb.theaccelerationoftheblocks.closetheMoonwouldhavetoorbitEarthSubstituteintotheequationfora.tobeattheRochelimit.ma�����3�m2gForaplanetandamoonwithidenticalm3�m2densities,theRochelimitis2.446timestheradiusoftheplanet.Earth’s�����3kg�2kg(9.80m/s2)3kg�2kgRochelimitis18,470km.�1.96m/s2107.Automobileenginesareratedbythetorquethattheyproduce.Researchand109.Ericsitsonasee-saw.Atwhatangle,rela-explainwhytorqueisanimportantquan-tivetothevertical,willthecomponentoftitytomeasure.hisweightparalleltotheplanebeequaltoone-thirdtheperpendicularcomponentofTheforceexertedbythegroundonthehisweight?(Chapter5)tireacceleratesthecar.Thisforceisproducedbytheengine.ItcreatestheFg,parallel�Fgsin�forcebyrotatingtheaxle.ThetorqueisFequaltotheforceontheedgeoftheg,perpendicular�Fgcos�tiremultipliedbytheradiusofthetire.Fg,perpendicular�3Fg,parallelGearsinthetransmissionmaycauseFg,perpendicularCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.theforcetochange,buttheydonot3���Fg,parallelchangethetorque.Therefore,theFamountoftorquecreatedbythegcos�13������engineisdeliveredtothewheels.Fgsin�tan���tan�1(3)�71.6°Physics:PrinciplesandProblemsSolutionsManual191
195Chapter8continued110.Thepilotofaplanewantstoreachan111.A60.0-kgspeedskaterwithavelocityofairport325kmduenorthin2.75hours.18.0m/scomesintoacurveof20.0-mAwindisblowingfromthewestatradius.Howmuchfrictionmustbeexerted30.0km/h.Whatheadingandairspeedbetweentheskatesandicetonegotiatetheshouldbechosentoreachthedestinationcurve?(Chapter6)ontime?(Chapter6)2mvF�Letgbethedistancenorthtotheair-f�Fnet�rport,xbethewestwarddeflection,and(60.0kg)(18.0m/s)2�����972Nhbetheactualdistancetraveled.First,20.0mfindtheheadingastheangle�traveledeastwardfromthenorthwardpath.ChallengeProblemvtan���xvypage208Ranktheobjectsshowninthediagramaccordingv��tan�1�x��totheirmomentsofinertiaabouttheindicatedvyaxes.Allsphereshaveequalmassesandallsepa-�1vxtyrationsarethesame.�tan���dybcda�tan�1�����(30.0km/h)(2.75h)A325km�14.3°westofnorthBTheairspeed,then,shouldbev2�v2�v2hxyC1v2�v2)�2�h�(vxy21d�2�y2D��v�2�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.xty(325km)2�1��(30.0km/h)2����2(2.75h)2�122km/h192SolutionsManualPhysics:PrinciplesandProblems
196CHAPTERMomentumandIts9ConservationPracticeProblemsimpulse�F�t�(�5.0�103N)(2.0s)9.1ImpulseandMomentumpages229–235��1.0�104N�sTheimpulseisdirectedwestwardpage233andhasamagnitudeof1.0�104N�s.1.Acompactcar,withmass725kg,ismovingat115km/htowardtheeast.Sketchtheb.Completethe“before”and“after”movingcar.sketches,anddeterminethemomentumandthevelocityofthecarnow.a.Findthemagnitudeanddirectionofitsmomentum.DrawanarrowonyourBeforeAftersketchshowingthemomentum.EpipfvpEp4kg�m/seastwardi�2.32�10p�mvF�t��p�pf�pi�(725kg)(115km/h)pf�F�t�pi1000m1h������1km3600s��1.0�104kg�m/s��2.32�104kg�m/seastward2.32�104kg�m/sb.Asecondcar,withamassof2175kg,�1.3�104kg�m/seastwardhasthesamemomentum.Whatisitsvelocity?pf�mvfv��ppf1.3�104kg�m/smvf���m���725kg(2.32�104kg�m/s)��3600�s���1k�m��18m/s1h1000m������2175kg�65km/heastward�38.4km/heastward3.A7.0-kgbowlingballisrollingdownthe2.Thedriverofthecompactcarintheprevi-alleywithavelocityof2.0m/s.Foreachousproblemsuddenlyappliesthebrakesimpulse,showninFigures9-3aand9-3b,hardfor2.0s.Asaresult,anaverageforcefindtheresultingspeedanddirectionofof5.0�103Nisexertedonthecartoslowitmotionofthebowlingball.down.a.b.�t�2.0s5512Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3N00F��5.0�1012�5�5Force(N)Force(N)a.Whatisthechangeinmomentum;thatis,themagnitudeanddirectionoftheTime(s)Time(s)impulse,onthecar?■Figure9-3Physics:PrinciplesandProblemsSolutionsManual193
197Chapter9continueda.F�t�pf�pi�mvf�mvi141kmF�t�mv65.0kmv��ff�m(5.0N)(1.0s)�(7.0kg)(2.0m/s)125.0km�����7.0kga.Whatistheaverageforceexertedonthe�2.7m/sinthesamedirectionperson?astheoriginalvelocityF�t��p�pf�piF�t�mvb.v��fpf�mF��f�pi�t(�5.0N)(1.0s)�(7.0kg)(2.0m/s)�����pf�mvi7.0kgF����t�1.3m/sinthesamedirection(0.0kg�m/s)�(60.0kg)(94km/h)astheoriginalvelocity������0.20s4.Thedriveracceleratesa240.0-kgsnowmo-���1000m���1h1km3600sbile,whichresultsinaforcebeingexertedthatspeedsupthesnowmobilefrom�7.8�103Noppositetothe6.00m/sto28.0m/soveratimeintervaldirectionofmotionof60.0s.b.Somepeoplethinkthattheycanstopa.Sketchtheevent,showingtheinitialtheirbodiesfromlurchingforwardinaandfinalsituations.vehiclethatissuddenlybrakingbyputtingtheirhandsonthedashboard.BeforeAfterFindthemassofanobjectthathasavivfweightequaltotheforceyoujustcalcu-lated.Couldyouliftsuchamass?Areyoustrongenoughtostopyourbody�xwithyourarms?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Whatisthesnowmobile’schangeinFg�mgmomentum?WhatistheimpulseonF3Ng7.8�102kgthesnowmobile?m���g��2�8.0�109.80m/s�p�F�tSuchamassistooheavytolift.You�m(vf�vi)cannotsafelystopyourselfwithyourarms.�(240.0kg)(28.0m/s�6.00m/s)�5.28�103kg�m/sc.WhatisthemagnitudeoftheaverageSectionReviewforcethatisexertedonthesnowmobile?9.1ImpulseandMomentum�p5.28�103kg�m/spages229–235F�������t60.0spage235�88.0N6.MomentumIsthemomentumofacartravelingsouthdifferentfromthatofthe5.Supposea60.0-kgpersonwasinthevehiclesamecarwhenittravelsnorthatthesamethathittheconcretewallinExamplespeed?Drawthemomentumvectorstosup-Problem1.Thevelocityofthepersonequalsportyouranswer.thatofthecarbothbeforeandafterthecrash,andthevelocitychangesin0.20s.Yes,momentumisavectorquantity,Sketchtheproblem.andthemomentaofthetwocarsareinoppositedirections.194SolutionsManualPhysics:PrinciplesandProblems
198Chapter9continuedpN�11.1kg�m/s�11.1N�sWEd.IfthebatandsoftballareincontactforS0.80ms,whatistheaverageforcethatthebatexertsontheball?F�t�m(vf�vi)pm(vf�vi)F����t7.ImpulseandMomentumWhenyoujumpfromaheighttotheground,youletyour(0.174kg)(38.0m/s�(�26.0m/s))����legsbendatthekneesasyourfeethitthe1s(0.80ms)����floor.Explainwhyyoudothisintermsof1000msthephysicsconceptsintroducedinthis�1.4�104Nchapter.Youreducetheforcebyincreasingthe10.MomentumThespeedofabasketballasitlengthoftimeittakestostoptheisdribbledisthesamewhentheballismotionofyourbody.goingtowardthefloorasitiswhentheballrisesfromthefloor.Isthebasketball’s8.MomentumWhichhasmoremomentum,changeinmomentumequaltozerowhenitasupertankertiedtoadockorafallinghitsthefloor?Ifnot,inwhichdirectionisraindrop?thechangeinmomentum?Drawthebas-ketball’smomentumvectorsbeforeandTheraindrophasmoremomentum,afterithitsthefloor.becauseasupertankeratresthaszeromomentum.No,thechangeinmomentumisupward.Beforetheballhitsthefloor,its9.ImpulseandMomentumA0.174-kgsoft-momentumvectorisdownward.Afterballispitchedhorizontallyat26.0m/s.Thetheballhitsthefloor,itsmomentumballmovesintheoppositedirectionatvectorisupward.38.0m/safteritishitbythebat.BeforeAftera.Drawarrowsshowingtheball’smomen-vftumbeforeandafterthebathitsit.pBeforeAfterpvi�yvivf�x11.AngularMomentumAnice-skaterspinsb.Whatisthechangeinmomentumofwithhisarmsoutstretched.Whenhepullstheball?hisarmsinandraisesthemabovehishead,�p�m(vf�vi)hespinsmuchfasterthanbefore.Dida�(0.174kg)torqueactontheice-skater?Ifnot,how(38.0m/s�(�26.0m/s))couldhisangularvelocityhaveincreased?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�11.1kg�m/sNotorqueactedonhim.Bydrawinghisarmsinandkeepingthemclosetothec.Whatistheimpulsedeliveredbythebat?axisofrotation,hedecreasedhisF�t�pf�pimomentofinertia.Becausetheangular��pmomentumdidnotchange,theskater’sangularvelocityincreased.Physics:PrinciplesandProblemsSolutionsManual195
199Chapter9continued12.CriticalThinkingAnarchershootsarrowsmv��PvPiatatarget.Someofthearrowsstickinthef�(mP�mG)target,whileothersbounceoff.Assuming(0.105kg)(24m/s)thatthemassesofthearrowsandtheveloc-�����0.034m/s(0.105kg�75kg)itiesofthearrowsarethesame,whicharrowsproduceabiggerimpulseonthetar-15.A35.0-gbulletstrikesa5.0-kgstationaryget?Hint:Drawadiagramtoshowthepieceoflumberandembedsitselfinthemomentumofthearrowsbeforeandafterhit-wood.Thepieceoflumberandbulletflytingthetargetforthetwoinstances.offtogetherat8.6m/s.Whatwastheorigi-Theonesthatbounceoffgivemorenalspeedofthebullet?impulsebecausetheyendupwithmbvbi�mwvwi�(mb�mw)vfsomemomentuminthereversedirec-tion,meaningtheyhavealargerchangewherevfisthecommonfinalspeedofinmomentum.thebulletandpieceoflumber.Becausevwi�0.0m/s,(mPracticeProblemsv��b�mw)vfbi�mb9.2Conservationof(0.0350kg�5.0kg)(8.6m/s)�����Momentum0.0350kgpages236–245�1.2�103m/spage23813.Twofreightcars,eachwithamassof16.A35.0-gbulletmovingat475m/sstrikesa3.0�105kg,collideandsticktogether.One2.5-kgbagofflourthatisonice,atrest.Thewasinitiallymovingat2.2m/s,andthebulletpassesthroughthebag,asshowninotherwasatrest.Whatistheirfinalspeed?Figure9-7,andexitsitat275m/s.Howfastisthebagmovingwhenthebulletexits?pi�pfCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mvAi�mvBi�2mvfvv��Ai�vBif�2275m/s2.2m/s�0.0m/s����2�1.1m/s14.A0.105-kghockeypuckmovingat24m/siscaughtandheldbya75-kggoalieatrest.Withwhatspeeddoesthegoalieslideontheice?■Figure9-7pPi�pGi�pPf�pGfmmBvBi�mFvFi�mBvBf�mFvFfPvPi�mGvGi�mPvPf�mGvGfwherevBecausevFi�0.0m/sGi�0.0kg�m/s,(mmv��BvBi�mBvBf)PvPi�(mP�mG)vfFf�mFwherevf�vPf�vGfisthecommonmB(vBi�vBf)finalspeedofthegoalieandthepuck.vFf���mF196SolutionsManualPhysics:PrinciplesandProblems
200Chapter9continued(0.0350kg)(475m/s�275m/s)�����2.5kg�2.8m/s17.Thebulletinthepreviousproblemstrikesa2.5-kgsteelballthatisatrest.Thebulletbouncesbackwardafteritscollisionataspeedof5.0m/s.Howfastistheballmovingwhenthebulletbouncesbackward?Thesystemisthebulletandtheball.mbulletvbullet,i�mballvball,i�mbulletvbullet,f�mballvball,fvball,i�0.0m/sandvbullet,f��5.0m/smbullet(vbullet,i�vbullet,f)(0.0350kg)(475m/s�(�5.0m/s))sov��������ball,f��m2.5kgball�6.7m/s18.A0.50-kgballthatistravelingat6.0m/scollideshead-onwitha1.00-kgballmovingintheoppositedirectionataspeedof12.0m/s.The0.50-kgballbouncesbackwardat14m/safterthecollision.Findthespeedofthesecondballafterthecollision.Saythatthefirstball(ballC)isinitiallymovinginthepositive(forward)direction.mCvCi�mDvDi�mCvCf�mDvDfmsov���CvCi�mDvDi�mCvCfDf�mD(0.50kg)(6.0m/s)�(1.00kg)(�12.0m/s)�(0.50kg)(�14m/s)���������1.00kg��2.0m/s,or2.0m/sintheoppositedirectionpage24019.A4.00-kgmodelrocketislaunched,expelling50.0gofburnedfuelfromitsexhaustataspeedof625m/s.Whatisthevelocityoftherocketafterthefuelhasburned?Hint:Ignoretheexternalforcesofgravityandairresistance.pri�pfuel,i�prf�pfuel,fwhereprf�pfuel,f�0.0kg�m/sIftheinitialmassoftherocket(includingfuel)ismr�4.00kg,thenthefinalmassoftherocketismrf�4.00kg�0.0500kg�3.95kg0.0kg�m/s�mrfvrf�mfuelvfuel,f�mv��fuelvfuel,fCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.rf�mrf�(0.0500kg)(�625m/s)����3.95kg�7.91m/sPhysics:PrinciplesandProblemsSolutionsManual197
201Chapter9continued20.Athreadholdsa1.5-kgcartanda4.5-kgcarttogether.Afterthethreadisburned,acompressedspringpushesthecartsapart,givingthe1.5-kgcartaspeedof27cm/stotheleft.Whatisthevelocityofthe4.5-kgcart?Letthe1.5-kgcartberepresentedby“C”andthe4.5-kgcartberepresentedby“D”.pCi�pDi�pCf�pDfwherepCi�pDi�0.0kg�m/smDvDf��mCvCf�msov�CvCfDf�mD�(1.5kg)(�27cm/s)����4.5kg�9.0cm/stotheright21.CarmenandJudidockacanoe.80.0-kgCarmenmovesforwardat4.0m/sassheleavesthecanoe.AtwhatspeedandinwhatdirectiondothecanoeandJudimoveiftheircombinedmassis115kg?pCi�pJi�pCf�pJfwherepCi�pJi�0.0kg�m/smCvCf��mJvJf�msov�CvCfJf�mJ�(80.0kg)(4.0m/s)����115kg�2.8m/sintheoppositedirectionCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page24322.A925-kgcarmovingnorthat20.1m/scollideswitha1865-kgcarmovingwestat13.4m/s.Thetwocarsarestucktogether.Inwhatdirectionandatwhatspeeddotheymoveafterthecollision?Before:pi,y�myvi,y�(925kg)(20.1m/s)�1.86�104kg�m/spi,x�mxvi,x�(1865kg)(�13.4m/s)��2.50�104kg�m/spf,y�pi,ypf,x�pi,xpf�pi���(pf,x)2��(pf�,y)2198SolutionsManualPhysics:PrinciplesandProblems
202Chapter9continued��(��2.50��104�kg�m�/s)2��(1.86�104kg��m/s)�2�3.12�104kg�m/spv��ff�m1�m23.12�104kg�m/s�����11.2m/s(925kg�1865kg)p�1f,y��tan���pf,x�11.86�104kg�m/s�tan������2.50�104kg�m/s�36.6°northofwest23.A1383-kgcarmovingsouthat11.2m/sisstruckbya1732-kgcarmovingeastat31.3m/s.Thecarsarestucktogether.Howfastandinwhatdirectiondotheymoveimmediatelyafterthecollision?Before:pi,x�p1,x�p2,x�0�m2v2ipi,y�p1,y�p2,y�m1v1i�0pf�pi���p1,x2��pi,y�2��(�m2v2�i)2�(m�1v1i)�2pv��ff�m1�m2�(�m2v2�i)2�(m�1v1i)�2����m1�m2�((1732��kg)(31.3m�/s))�2��((1383kg)(���11.2�m/s))2��������1383kg�1782kg�18.1m/s�1pi,y�1m1v1i�1(1383kg)(�11.2m/s)��tan����tan����tan������15.9°pm(1732kg)(31.3m/s)i,x2v2isouthofeast24.Astationarybilliardball,withamassof0.17kg,isstruckbyanidenticalballmovingat4.0m/s.Afterthecollision,thesecondballmoves60.0°totheleftofitsoriginaldirection.Thestationaryballmoves30.0°totherightofthemovingCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ball’soriginaldirection.Whatisthevelocityofeachballafterthecollision?pCi�pDi�pCf�pDfwherepCi�0.0kg�m/smC�mD�m�0.17kgPhysics:PrinciplesandProblemsSolutionsManual199
203Chapter9continuedvDfVectorDiagramDf60.0�pDiDiCivDi30.0�30.0�60.0�CfpCfpDfvCfThevectordiagramprovidesfinalmomentumequationsfortheballthatisinitiallystationary,C,andtheballthatisinitiallymoving,D.pCf�pDisin60.0°pDf�pDicos60.0°Wecanusethemomentumequationforthestationaryballtofinditsfinalvelocity.pCf�pDisin60.0°mvCf�mvDisin60.0°vCf�vDisin60.0°�(4.0m/s)(sin60.0°)�3.5m/s,30.0°totherightWecanusethemomentumequationforthemovingballtofinditsvelocity.pDf�pDicos60.0°mvDf�mvDicos60.0°vDf�vDicos60.0°Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(4.0m/s)(cos60.0°)�2.0m/s,60.0°totheleft25.A1345-kgcarmovingeastat15.7m/sisstruckbya1923-kgcarmovingnorth.Theyarestucktogetherandmovewithaninitialvelocityof14.5m/sat��63.5°.Wasthenorth-movingcarexceedingthe20.1m/sspeedlimit?Before:pi,x�m1v1,i�(1345kg)(15.7m/s)�2.11�104kg�m/spf�pi�(m1�m2)vf�(1345kg�1923kg)(14.5m/s)�4.74�104kg�m/spf,y�pfsin��(4.74�104kg�m/s)(sin63.5°)�4.24�104kg�m/s200SolutionsManualPhysics:PrinciplesandProblems
204Chapter9continuedpwheref,y�pi,y�m2v2,ipf,y4.24�104kg�m/sF�Fgv����a��andm��2,i��m1923kgmg2F�22.1m/sgsin�so,a���gsin�FYes,itwasexceedingthespeedlimit.g/gThevelocityandaccelerationofthecartarerelatedbythemotionequa-SectionReviewtion,v2�v2�2a(d�dii)withv9.2Conservationofi�0anddi�0.Thus,Momentumv2�2adpages236–245v��2�adpage245��(2)(�gsin��)(d)�26.AngularMomentumTheouterrimofaplasticdiskisthickandheavy.Besidesmak-��(2)(9.8��0m/s2�)(sin30.0°)�(1.00m�)�ingiteasiertocatch,howdoesthisaffect�3.13m/stherotationalpropertiesoftheplasticdisk?b.Ifthetwocartssticktogether,withwhatMostofthemassofthediskislocatedinitialspeedwilltheymovealong?attherim,therebyincreasingitsmmomentofinertia.Therefore,whentheCvCi�(mC�mC)vfdiskisspinning,itsangularmomentummCvCiso,v��f�mislargerthanitwouldbeifmoremassC�mDwerenearthecenter.WithalargerF���C�angularmomentum,thediskfliesgvCi��throughtheairwithmorestability.FF��C���Dgg27.SpeedAcart,weighing24.5N,isreleasedF���CvCifromrestona1.00-mramp,inclinedatanFC�FDangleof30.0°asshowninFigure9-14.Thecartrollsdowntheinclineandstrikesa����(24.5N)(3.13m/s)24.5N�36.8Nsecondcartweighing36.8N.�1.25m/s24.5N28.ConservationofMomentumDuringatennisserve,theracketofatennisplayercontinuesforwardafterithitstheball.Ismomentumconservedinthecollision?1.0Explain,makingsurethatyoudefinethe0m36.8Nsystem.No,becausethemassoftheracketis30.0°muchlargerthanthatoftheball,onlya■Figure9-14smallchangeinitsvelocityisrequired.Inaddition,itisbeingheldbyamas-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Calculatethespeedofthefirstcartatsive,movingarmthatisattachedtoathebottomoftheincline.bodyincontactwithEarth.Thus,theTheforceparalleltothesurfaceofracketandballdonotcompriseantherampisisolatedsystem.F��Fgsin�29.MomentumApole-vaulterrunstowardthePhysics:PrinciplesandProblemsSolutionsManual201
205Chapter9continuedlaunchpointwithhorizontalmomentum.Wheredoestheverticalmomentumcomeaverageforcetimeoverwhichtheforceisexertedfromastheathletevaultsoverthecrossbar?ProductistheTheverticalmomentumcomesfromtheimpulsiveforceofEarthagainstimpulsethepole.Earthacquiresanequalandoppositeverticalmomentum.Producesachangeinmomentum30.InitialMomentumDuringasoccergame,twoplayerscomefromoppositedirectionsandcollidewhentryingtoheadtheball.ProductisthemassvelocityTheycometorestinmidairandfalltotheground.Describetheirinitialmomenta.Becausetheirfinalmomentaarezero,MasteringConceptstheirinitialmomentawereequalandopposite.page25033.Canabullethavethesamemomentumasa31.CriticalThinkingYoucatchaheavyballtruck?Explain.(9.1)whileyouarestandingonaskateboard,Yes,forabullettohavethesameandthenyourollbackward.Ifyouweremomentumasatruck,itmusthaveastandingontheground,however,youhighervelocitybecausethetwomasseswouldbeabletoavoidmovingwhilecatch-arenotthesame.ingtheball.Explainbothsituationsusingmbulletvbullet�mtruckvtruckthelawofconservationofmomentum.Explainwhichsystemyouuseineachcase.34.Apitcherthrowsacurveballtothecatcher.Inthecaseoftheskateboard,theball,Assumethatthespeedoftheballdoesn’ttheskateboard,andyouareanisolatedchangeinflight.(9.1)system,andthemomentumoftheballa.WhichplayerexertsthelargerimpulseCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.isshared.Inthesecondcase,unlessontheball?Earthisincluded,thereisanexternalThepitcherandthecatcherexertforce,somomentumisnotconserved.thesameamountofimpulseontheIfEarth’slargemassisincludedintheball,butthetwoimpulsesareinsystem,thechangeinitsvelocityisoppositedirections.negligible.b.Whichplayerexertsthelargerforceontheball?ChapterAssessmentThecatcherexertsthelargerforceontheballbecausethetimeintervalConceptMappingoverwhichtheforceisexertedispage250smaller.32.Completethefollowingconceptmapusingthefollowingterms:mass,momentum,aver-35.Newton’ssecondlawofmotionstatesthatageforce,timeoverwhichtheforceisexerted.ifnonetforceisexertedonasystem,noaccelerationispossible.Doesitfollowthatnochangeinmomentumcanoccur?(9.1)Nonetforceonthesystemmeansnonetimpulseonthesystemandnonetchangeinmomentum.However,individ-ualpartsofthesystemmayhavea202SolutionsManualPhysics:PrinciplesandProblems
206Chapter9continuedchangeinmomentumaslongastheThemomentumofafallingballisnetchangeinmomentumiszero.notconservedbecauseanetexter-nalforce,gravity,isactingonit.36.Whyarecarsmadewithbumpersthatcanb.Inwhatsystemthatincludesthefallingbepushedinduringacrash?(9.1)ballisthemomentumconserved?Carsaremadewithbumpersthatcom-Onesuchsysteminwhichtotalpressduringacrashtoincreasethemomentumisconservedincludestimeofacollision,therebyreducingthetheballplusEarth.force.42.Afallingbasketballhitsthefloor.Just37.Anice-skaterisdoingaspin.(9.1)beforeithits,themomentumisinthea.Howcantheskater’sangularmomen-downwarddirection,andafterithitsthetumbechanged?floor,themomentumisintheupwardbyapplyinganexternaltorquedirection.(9.2)b.Howcantheskater’sangularvelocitybea.Whyisn’tthemomentumofthebasket-changedwithoutchangingtheangularballconservedeventhoughthebouncemomentum?isacollision?bychangingthemomentofinertiaThefloorisoutsidethesystem,soitexertsanexternalforce,andthere-38.Whatismeantby“anisolatedsystem?”fore,animpulseontheball.(9.2)b.Inwhatsystemisthemomentumcon-Anisolatedsystemhasnoexternalserved?forcesactingonit.Momentumisconservedinthesys-temofballplusEarth.39.Aspacecraftinouterspaceincreasesitsvelocitybyfiringitsrockets.Howcanhot43.Onlyanexternalforcecanchangethegasesescapingfromitsrocketenginemomentumofasystem.Explainhowthechangethevelocityofthecraftwhenthereinternalforceofacar’sbrakesbringsthecarisnothinginspaceforthegasestopushtoastop.(9.2)against?(9.2)Theexternalforceofacar’sbrakescanMomentumisconserved.Thechangeinbringthecartoastopbystoppingthemomentumofgasesinonedirectionwheelsandallowingtheexternalfric-mustbebalancedbyanequalchangetionalforceoftheroadagainstthetiresinmomentumofthespacecraftinthetostopthecar.Ifthereisnofriction—oppositedirection.forexample,iftheroadisicy—thenthereisnoexternalforceandthecar40.Acueballtravelsacrossapooltableanddoesnotstop.collideswiththestationaryeightball.Thetwoballshaveequalmasses.Afterthecolli-44.Children’splaygroundsoftenhavecircular-sion,thecueballisatrest.Whatmustbemotionrides.Howcouldachildchangethetrueregardingthespeedoftheeightball?angularmomentumofsucharideasitis(9.2)turning?(9.2)TheeightballmustbemovingwiththeThechildwouldhavetoexertatorqueCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.samevelocitythatthecueballhadjustonit.Heorshecouldstandnexttoitbeforethecollision.andexertaforcetangentialtothecircleonthehandlesastheygopast.Heor41.ConsideraballfallingtowardEarth.(9.2)shealsocouldrunattherideandjumpa.Whyisthemomentumoftheballnotonboard.conserved?Physics:PrinciplesandProblemsSolutionsManual203
207Chapter9continuedApplyingConceptsAftertimeA,theobjectmoveswithaconstant,positivevelocity.AftertimeB,pages250–251theobjectisatrest.AftertimeC,the45.Explaintheconceptofimpulseusingphysi-objectmoveswithaconstant,negativecalideasratherthanmathematics.velocity.Aforce,F,exertedonanobjectoveratime,�t,causesthemomentumofthe50.Duringaspacewalk,thetetherconnectingobjecttochangebythequantityF�t.anastronauttothespaceshipbreaks.Usingagaspistol,theastronautmanagestogetback46.Isitpossibleforanobjecttoobtainalargertotheship.Usethelanguageoftheimpulse-impulsefromasmallerforcethanitdoesmomentumtheoremandadiagramtofromalargerforce?Explain.explainwhythismethodwaseffective.Yes,ifthesmallerforceactsforalongWhenthegaspistolisfiredintheoppo-enoughtime,itcanprovidealargersitedirection,itprovidestheimpulseimpulse.neededtomovetheastronauttowardthespaceship.47.FoulBallYouaresittingatabaseballgamewhenafoulballcomesinyourdirection.Youpreparetocatchitbare-handed.Tocatchitsafely,shouldyoumoveyourhandstowardtheball,holdthemstill,ormovetheminthesamedirectionasthemoving�pball?Explain.Youshouldmoveyourhandsinthesamedirectiontheballistravelingtoincreasethetimeofthecollision,therebyreducingtheforce.�p48.A0.11-gbulletleavesapistolat323m/s,51.TennisBallAsatennisballbouncesoffaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.whileasimilarbulletleavesarifleat396wall,itsmomentumisreversed.Explainthism/s.Explainthedifferenceinexitspeedsofactionintermsofthelawofconservationofthetwobullets,assumingthattheforcesmomentum.Definethesystemanddrawaexertedonthebulletsbytheexpandingdiagramasapartofyourexplanation.gaseshavethesamemagnitude.BeforeAfterThebulletisintheriflealongertime,ppsothemomentumitgainsislarger.vivf49.AnobjectinitiallyatrestexperiencestheimpulsesdescribedbythegraphinFigure9-15.Describetheobject’spEarthandwallmotionafterimpulsesA,B,andC.+x2Considerthesystemtobetheball,theAwall,andEarth.ThewallandEarthgain6810110somemomentuminthecollision.24BCForce(N)�252.ImaginethatyoucommandspaceshipZeldon,whichismovingthroughinterplan-Time(s)etaryspaceathighspeed.Howcouldyou■Figure9-15204SolutionsManualPhysics:PrinciplesandProblems
208Chapter9continuedslowyourshipbyapplyingthelawofcon-MasteringProblemsservationofmomentum?9.1ImpulseandMomentumByshootingmassintheformofpages251–252exhaustgas,athighvelocityintheLevel1samedirectioninwhichyouaremov-56.GolfRocíostrikesa0.058-kggolfballwithing,itsmomentumwouldcausetheaforceof272Nandgivesitavelocityofship’smomentumtodecrease.62.0m/s.HowlongwasRocío’sclubincontactwiththeball?53.Twotrucksthatappeartobeidenticalcol-lideonanicyroad.Onewasoriginallyatm�v(0.058kg)(62.0m/s)�t������rest.ThetrucksarestucktogetherandmoveF272Natmorethanhalftheoriginalspeedofthe�0.013smovingtruck.Whatcanyouconcludeaboutthecontentsofthetwotrucks?57.A0.145-kgbaseballispitchedat42m/s.ThebatterhitsithorizontallytothepitcherIfthetwotruckshadequalmasses,at58m/s.theywouldhavemovedoffathalfthespeedofthemovingtruck.Thus,thea.Findthechangeinmomentumofthemovingtruckmusthavehadamoreball.massiveload.Takethedirectionofthepitchtobepositive.54.Explain,intermsofimpulseandmomen-�p�mvf�mvi�m(vf�vi)tum,whyitisadvisabletoplacethebuttofarifleagainstyourshoulderwhenfirst�(0.145kg)(�58m/s�(�42m/s))learningtoshoot.��14kg�m/sWhenheldloosely,therecoilmomen-b.Iftheballandbatareincontactfortumoftherifleworksagainstonlythe4.6�10�4s,whatistheaverageforcemassoftherifle,therebyproducingaduringcontact?largervelocityandstrikingyourshoul-F�t��pder.Therecoilmomentummustwork�pagainstthemassoftherifleandyou,F���tresultinginasmallervelocity.m(vf�vi)���55.BulletsTwobulletsofequalmassareshot�tatequalspeedsatblocksofwoodona(0.145kg)(�58m/s�(�42m/s))������44.6�10ssmoothicerink.Onebullet,madeofrub-ber,bouncesoffofthewood.Theother��3.2�104Nbullet,madeofaluminum,burrowsintothewood.Inwhichcasedoestheblockof58.BowlingAforceof186Nactsona7.3-kgwoodmovefaster?Explain.bowlingballfor0.40s.Whatisthebowlingball’schangeinmomentum?WhatisitsMomentumisconserved,sothechangeinvelocity?momentumoftheblockandbulletafterthecollisionequalsthemomentumof�p�F�tthebulletbeforethecollision.Therub-�(186N)(0.40s)berbullethasanegativemomentumCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�74N�safterimpact,withrespecttotheblock,�74kg�m/ssotheblock’smomentummustbegreaterinthiscase.�p�v��mF�t��mPhysics:PrinciplesandProblemsSolutionsManual205
209Chapter9continued62.HockeyAhockeyplayermakesaslapshot,(186N)(0.40s)���7.3kgexertingaconstantforceof30.0Nonthe1m/shockeypuckfor0.16s.Whatisthemagni-�1.0�10tudeoftheimpulsegiventothepuck?59.A5500-kgfreighttruckacceleratesF�t�(30.0N)(0.16s)from4.2m/sto7.8m/sin15.0sby�4.8N�stheapplicationofaconstantforce.a.Whatchangeinmomentumoccurs?63.SkateboardingYourbrother’smassis35.6kg,andhehasa1.3-kgskateboard.�p�m�v�m(vf�vi)Whatisthecombinedmomentumofyour�(5500kg)(7.8m/s�4.2m/s)brotherandhisskateboardiftheyaremov-�2.0�104kg�m/singat9.50m/s?p�mvb.Howlargeofaforceisexerted?�(m�pboy�mboard)vF���t�(35.6kg�1.3kg)(9.50m/s)m(v���f�vi)�3.5�102kg�m/s�t�����(5500kg)(7.8m/s�4.2m/s)64.Ahockeypuckhasamassof0.115kgand15.0sisatrest.Ahockeyplayermakesashot,�1.3�103Nexertingaconstantforceof30.0Nonthepuckfor0.16s.Withwhatspeeddoesit60.Inaballisticstestatthepolicedepartment,headtowardthegoal?OfficerRiosfiresa6.0-gbulletat350m/sF�t�m�v�m(vf�vi)intoacontainerthatstopsitin1.8ms.Whatistheaverageforcethatstopsthebullet?wherevi�0�pF�tF���tThusvf��mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.m(vf�vi)���(30.0N)(0.16s)����t0.115kg(0.0060kg)(0.0m/s�350m/s)�42m/s�����1.8�10�3s��1.2�103N65.Beforeacollision,a25-kgobjectwasmov-ingat�12m/s.Findtheimpulsethatacted61.VolleyballA0.24-kgvolleyballapproachesontheobjectif,afterthecollision,itmovedTinawithavelocityof3.8m/s.Tinabumpsatthefollowingvelocities.theball,givingitaspeedof2.4m/sbutina.�8.0m/stheoppositedirection.WhataverageforceF�t�m�v�m(vf�vi)didsheapplyiftheinteractiontimebetweenherhandsandtheballwas0.025s?�(25kg)(8.0m/s�12m/s)m�v��1.0�102kg�m/sF���tb.�8.0m/s(0.24kg)(�2.4m/s�3.8m/s)�����F�t�m�v�m(v0.025sf�vi)��6.0�101N�(25kg)(�8.0m/s�12m/s)��5.0�102kg�m/s206SolutionsManualPhysics:PrinciplesandProblems
210Chapter9continuedLevel266.A0.150-kgball,movinginthepositivedirection2at12m/s,isactedonbytheimpulseshowninthegraphinFigure9-16.Whatistheball’s0speedat4.0s?1234Force(N)F�t�m�v�2Areaofgraph�m�vTime(s)1�2(2.0N)(2.0s)�m(vf�vi)■Figure9-162.0N�s�(0.150kg)(vf�12m/s)2.0kg�m/sv��f��0.150kg12m/s�25m/s67.BaseballA0.145-kgbaseballismovingat35m/swhenitiscaughtbyaplayer.a.Findthechangeinmomentumoftheball.�p�m(vf�vi)�(0.145kg)(0.0m/s�35m/s)��5.1kg�m/sb.Iftheballiscaughtwiththemittheldinastationarypositionsothattheballstopsin0.050s,whatistheaverageforceexertedontheball?�p�Faverage�t�pm(vf�vi)so,F���average���t�t(0.145kg)(0.0m/s�35m/s)�����0.500s��1.0�102Nc.If,instead,themittismovingbackwardsothattheballtakes0.500stostop,whatistheaverageforceexertedbythemittontheball?�p�Faverage�t�pm(vf�vi)so,F���average���t�t(0.145kg)(0.0m/s�35m/s)�����0.500s��1.0�101N68.HockeyAhockeypuckhasamassof0.115kgandstrikesthepoleofthenetat37m/s.Itbouncesoffintheoppositedirectionat25m/s,asshowninFigure9-17.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Whatistheimpulseonthepuck?F�t�m(vf�vi)0.115kg�(0.115kg)(�25m/s�37m/s)25m/s��7.1kg�m/s■Figure9-17Physics:PrinciplesandProblemsSolutionsManual207
211Chapter9continuedb.Ifthecollisiontakes5.0�10�4s,whatistheaverageforceonthepuck?F�t�m(vf�vi)m(vF���f�vi)�t(0.115kg)(�25m/s�37m/s)������45.0�10s��1.4�104N69.Anitrogenmoleculewithamassof4.7�10�26kg,movingat550m/s,strikesthewallofacontainerandbouncesbackatthesamespeed.a.Whatistheimpulsethemoleculedeliverstothewall?F�t�m(vf�vi)�(4.7�10�26kg)(�550m/s�550m/s)��5.2�10�23kg�m/sTheimpulsethewalldeliverstothemoleculeis�5.2�10�23kg�m/s.Theimpulsethemoleculedeliverstothewallis�5.2�10�23kg�m/s.b.Ifthereare1.5�1023collisionseachsecond,whatistheaverageforceonthewall?F�t�m(vf�vi)m(vF���f�vi)�tForallthecollisions,theforceism(vF23)��f�vi)total�(1.5�10�t(4.7�10�26kg)(�550m/s�550m/s)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(1.5�1023)�����1.0s�7.8NLevel370.RocketsSmallrocketsareusedtomaketinyadjustmentsinthespeedsofsatellites.Onesuchrockethasathrustof35N.Ifitisfiredtochangethevelocityofa72,000-kgspacecraftby63cm/s,howlongshoulditbefired?F�t�m�vm�tso,�t��F(72,000kg)(0.63m/s)����35N�1.3�103s,or22min208SolutionsManualPhysics:PrinciplesandProblems
212Chapter9continued71.Ananimalrescueplaneflyingdueeastat36.0m/sdropsabale36.0m/sofhayfromanaltitudeof60.0m,asshowninFigure9-18.Ifthebaleofhayweighs175N,whatisthemomentumofthebalethemomentbeforeitstrikestheground?Givebothmagni-175Ntudeanddirection.Firstuseprojectilemotiontofindthevelocityofthebale.p�mv60.0mTofindv,considerthehorizontalandverticalcomponents.vx�36.0m/sv2�v2�2dg�2dg■Figure9-18yiyThus,v��v�x2�v�y2��v�x2�2�dgThemomentum,then,isFgvFg�v�x2�2�dgp�����gg(175N)�(36.0�m/s)�2��(2)(60.0m�)(9.80��m/s2)�������9.80m/s2�888kg�m/sTheanglefromthehorizontalisvytan���vx�2�dg��vx�(2)(60�.0m)(�9.80m�/s�2)����36.0m/s�43.6°72.AccidentAcarmovingat10.0m/scrashesintoabarrierandstopsin0.050s.Thereisa20.0-kgchildinthecar.Assumethatthechild’svelocityischangedbythesameamountasthatofthecar,andinthesametimeperiod.a.Whatistheimpulseneededtostopthechild?F�t�m�v�m(vf�vi)�(20.0kg)(0.0m/s�10.0m/s)��2.00�102kg�m/sb.Whatistheaverageforceonthechild?F�t�m�v�m(vf�vi)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.m(vso,F���f�vi)�t(20.0kg)(0.0m/s�10.0m/s)�����0.050s��4.0�103NPhysics:PrinciplesandProblemsSolutionsManual209
213Chapter9continuedc.WhatistheapproximatemassofanBeforeobjectwhoseweightequalstheforceinvFBvDTpartb?Fg�mgFg4.0�103Nso,m�����g9.80m/s2�4.1�102kgd.Couldyouliftsuchaweightwithyour+xarm?No.Aftere.WhyisitadvisabletouseapropervFB�vDT�0restrainingseatratherthanholdachildonyourlap?Youwouldnotbeabletoprotectachildonyourlapintheeventofacollision.9.2ConservationofMomentum+xpages252–253b.Whatwasthefullback’smomentumLevel1beforethecollision?73.FootballA95-kgfullback,runningatp8.2m/s,collidesinmidairwitha128-kgFB�mFBvFB�(95kg)(8.2m/s)defensivetacklemovingintheopposite�7.8�102kg�m/sdirection.Bothplayersendupwithzeroc.Whatwasthechangeinthefullback’sspeed.momentum?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Identifythe“before”and“after”situa-�pFB�pf�pFBtionsanddrawadiagramofboth.�0�p2kg�m/sBefore:mFB��7.8�10FB�95kgd.WhatwasthechangeinthedefensivevFB�8.2m/stackle’smomentum?mDT�128kg�7.8�102kg�m/svDT�?e.Whatwasthedefensivetackle’soriginalmomentum?After:m�223kgv�7.8�102kg�m/sf�0m/sf.Howfastwasthedefensivetacklemov-ingoriginally?m2kg�m/sDTvDT��7.8�10�7.8�102kg�m/sso,v���DT�128kg��6.1m/s210SolutionsManualPhysics:PrinciplesandProblems
214Chapter9continued74.MarbleC,withmass5.0g,movesatad.CalculatethemomentumofmarbleDspeedof20.0cm/s.Itcollideswithasec-afterthecollision.ondmarble,D,withmass10.0g,movingatpCi�pDi�pCf�pDf10.0cm/sinthesamedirection.Afterthepcollision,marbleCcontinueswithaspeedDf�pCi�pDi�pCfof8.0cm/sinthesamedirection.�1.00�10�3kg�m/s�a.Sketchthesituationandidentifythesys-1.00�10�3kg�m/s�tem.Identifythe“before”and“after”sit-4.0�10�4kg�m/suationsandsetupacoordinatesystem.�1.6�10�3kg�m/sBefore:mC�5.0ge.WhatisthespeedofmarbleDafterthemD�10.0gcollision?vCi�20.0cm/spDf�mDvDfvDi�10.0cm/spDfso,v�Df�mDAfter:mC�5.0g1.6�10�3kg�m/sm�����2D�10.0g1.00�10kgvCf�8.0cm/s�1.6�10�1m/s�0.16m/sv�16cm/sDf�?Before75.TwolabcartsarepushedtogetherwithaspringmechanismcompressedbetweenvCivDithem.Uponrelease,the5.0-kgcartrepelsCDonewaywithavelocityof0.12m/s,whilethe2.0-kgcartgoesintheoppositedirec-tion.Whatisthevelocityofthe2.0-kgcart?+xm1vi��m2vfmAfterv�1�vif��m2(5.0kg)(0.12m/s)vCfvDf����CD�(2.0kg)��0.30m/s+x76.A50.0-gprojectileislaunchedwithahori-zontalvelocityof647m/sfroma4.65-kgb.Calculatethemarbles’momentabeforelaunchermovinginthesamedirectionatthecollision.2.00m/s.Whatisthelauncher’svelocitym�3kg)(0.200m/s)afterthelaunch?CvCi�(5.0�10p�1.0�10�3kg�m/sCi�pDi�pCf�pDfmm�2kg)(0.100m/s)CvCi�mDvDi�mCvCf�mDvDfDvDi�(1.00�10mso,v���CvCi�mDvDi�mCvCfCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.0�10�3kg�m/sDf�mDc.CalculatethemomentumofmarbleCAssumingthattheprojectile,C,isafterthecollision.launchedinthedirectionofthem�3kg)(0.080m/s)CvCf�(5.0�10launcher,D,motion,�4.0�10�4kg�m/sPhysics:PrinciplesandProblemsSolutionsManual211
215Chapter9continued(0.0500kg)(2.00m/s)�(4.65kg)(2.00m/s)�(0.0500kg)(647m/s)v��������Df�4.65kg��4.94m/s,or4.94m/sbackwardsLevel277.A12.0-grubberbullettravelsatavelocityof150m/s,hitsastationary8.5-kgconcreteblockrestingonafrictionlesssurface,andricochetsintheoppositedirectionwithavelocityof�1.0�102m/s,asshowninFigure9-19.Howfastwilltheconcrete2�1.0�10m/s8.5kgblockbemoving?mCvCi�mDvDi�mCvCf�mDvDf12.0gmv���CvCi�mDvDi�mCvCfDf�m■Figure9-19Dsincetheblockisinitiallyatrest,thisbecomesmv��C(vCi�vCf)Df�mD(0.0120kg)(150m/s�(�1.0�102m/s))������8.5kg�0.35m/s78.SkateboardingKofi,withmass42.00kg,isridingaskateboardwithamassof2.00kgandtravelingat1.20m/s.Kofijumpsoffandtheskateboardstopsdeadinitstracks.Inwhatdirectionandwithwhatvelocitydidhejump?(mLvLi�msvsi)vi�mLvLf�msvsfCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.wherevsf�0andvLi�vsi�vi(mThusv��L�ms)viLf�mL(42.00kg�2.00kg)(1.20m/s)�����42.00kg�1.26m/sinthesamedirectionasshewasriding79.BilliardsAcueball,withmass0.16kg,rollingat4.0m/s,hitsastationaryeightballofsimilarmass.Ifthecueballtravels45°aboveitsoriginalpathandtheeightballtravels45°belowthehorizontal,asshowninFigure9-20,whatisthevelocityofeachballafterthecollision?212SolutionsManualPhysics:PrinciplesandProblems
216Chapter9continued80.A2575-kgvanrunsintothebackofan825-kgcompactcaratrest.Theymoveofftogetherat8.5m/s.Assumingthatthefric-tionwiththeroadisnegligible,calculatetheinitialspeedofthevan.pCi�pDi�pCf�pDfm45°CvCi�(mC�mD)vfmso,v��C�mD45°Ci�mC(2575kg�825kg)(8.5m/s)v����f�2575kg�11m/sLevel381.In-lineSkatingDiegoandKeshiaareon■Figure9-20in-lineskatesandstandface-to-face,thenpusheachotherawaywiththeirhands.pCiDiegohasamassof90.0kgandKeshiahas45�amassof60.0kg.p8fpa.Sketchtheevent,identifyingtheCf“before”and“after”situations,andsetupacoordinateaxis.Wecangetmomentumequationsfromthevectordiagram.Before:mK�60.0kgpCf�pCisin45°mD�90.0kgmCvCf�mCvCisin45°vi�0.0m/svCf�vCisin45°After:mK�60.0kg�(4.0m/s)(sin45°)mD�90.0kg�2.8m/svKf�?Fortheeightball,vpDf�?8f�pcicos45°m8v8f�mCvCi(cos45°)wherem8�mC.Thus,v8f�vCicos45°�(4.0m/s)(cos45°)�2.8m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual213
217Chapter9continuedBeforevKi�vDi�0+xAftervKfvDf+xb.Findtheratiooftheskaters’velocitiesjustaftertheirhandslosecontact.pKi�pDi�0.0kg�m/s�pKf�pDfso,mKvKf�mDvDf�0.0kg�m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.andmKvKf��mDvDfThus,theratiosofthevelocitiesarevKfmD90.0kg�������������1.50vm60.0kgDfKThenegativesignshowsthatthevelocitiesareinoppositedirections.c.Whichskaterhasthegreaterspeed?Keshia,whohasthesmallermass,hasthegreaterspeed.d.Whichskaterpushedharder?Theforceswereequalandopposite.82.A0.200-kgplasticballmoveswithavelocityof0.30m/s.Itcollideswithasecondplasticballofmass0.100kg,whichismovingalongthesamelineataspeedof0.10m/s.Afterthecollision,bothballscontinuemovinginthesame,originaldirection.Thespeedofthe0.100-kgballis0.26m/s.Whatisthenewvelocityofthe0.200-kgball?mCvCi�mDvDi�mCvCf�mDvDfmso,v���CvCi�mDvDi�mDvDfCf�mC214SolutionsManualPhysics:PrinciplesandProblems
218Chapter9continued(0.200kg)(0.30m/s)�(0.100kg)(0.10m/s)�(0.100kg)(0.26m/s)���������0.200kg�0.22m/sintheoriginaldirectionMixedReviewpages253–254Level183.Aconstantforceof6.00Nactsona3.00-kgobjectfor10.0s.Whatarethechangesintheobject’smomentumandvelocity?Thechangeinmomentumis�p�F�t�(6.00N)(10.0s)�60.0N�s�60.0kg�m/sThechangeinvelocityisfoundfromtheimpulse.F�t�m�vF�t�v��m(6.00N)(10.0s)���3.00kg�20.0m/s84.Thevelocityofa625-kgcarischangedfrom10.0m/sto44.0m/sin68.0sbyanexternal,constantforce.a.Whatistheresultingchangeinmomentumofthecar?�p�m�v�m(vf�vi)�(625kg)(44.0m/s�10.0m/s)�2.12�104kg�m/sb.Whatisthemagnitudeoftheforce?F�t�m�vm�vso,F���tm(v���f�vi)�t(625kg)(44.0m/s�10.0m/s)�����68.0s�313N85.DragsterAn845-kgdragsteracceleratesonaracetrackfromrestto100.0km/hin0.90s.a.Whatisthechangeinmomentumofthedragster?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�p�m(vf�vi)1000m1h�(845kg)(100.0km/h�0.0km/h)������1km3600s�2.35�104kg�m/sPhysics:PrinciplesandProblemsSolutionsManual215
219Chapter9continuedb.Whatistheaverageforceexertedonthedragster?m(vF���f�vi)�t(845kg)(100.0km/h�0.0km/h)1000m1h�����������0.90s1km3600s�2.6�104Nc.Whatexertsthatforce?Theforceisexertedbythetrackthroughfriction.Level286.IceHockeyA0.115-kghockeypuck,movingat35.0m/s,strikesa0.365-kgjacketthatisthrownontotheicebyafanofacertainhockeyteam.Thepuckandjacketslideofftogether.Findtheirvelocity.mPvPi�(mP�mJ)vfmv��PmPif�mP�mJ(0.115kg)(35.0m/s)����(0.115kg�0.365kg)�8.39m/s87.A50.0-kgwoman,ridingona10.0-kgcart,ismovingeastat5.0m/s.Thewomanjumpsoffthefrontofthecartandlandsonthegroundat7.0m/seastward,rela-tivetotheground.a.Sketchthe“before”and“after”situationsandassignacoordinateaxistothem.Before:mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.w�50.0kgmc�10.0kgvi�5.0m/sAfter:mw�50.0kgmc�10.0kgvwf�7.0m/svcf�?BeforeAftervivwfvCf+x216SolutionsManualPhysics:PrinciplesandProblems
220Chapter9continuedb.Findthecart’svelocityafterthewomanjumpsoff.(mw�mc)vi�mwvwf�mcvcf(mso,v���w�mc)vi�mwvwfcf�mc(50.0kg�10.0kg)(5.0m/s)�(50.0kg)(7.0m/s)�������10.0kg��5.0m/s,or5.0m/swest88.GymnasticsFigure9-21showsagymnastperformingaroutine.First,shedoesgiantswingsonthehighbar,holdingherbodystraightandpivotingaroundherhands.Then,sheletsgoofthehighbarandgrabsherkneeswithherhandsinthetuckposition.Finally,shestraightensupandlandsonherfeet.a.Inthesecondandfinalpartsofthegymnast’sroutine,aroundwhataxisdoesshespin?Shespinsaroundthecenterofmassofherbody,firstinthetuckposi-tionandthenalsoasshestraightensout.b.Rankinorder,fromgreatesttoleast,hermomentsofinertiaforthethreepositions.giantswing(greatest),straight,tuck(least)c.Rankinorder,fromgreatesttoleast,herangularvelocitiesinthethreepositions.tuck(greatest),straight,giantswing(least)■Figure9-21Level389.A60.0-kgmaledancerleaps0.32mhigh.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Withwhatmomentumdoeshereachtheground?v�v2�2dg0Thus,thevelocityofthedancerisv��2�dgPhysics:PrinciplesandProblemsSolutionsManual217
221Chapter9continuedandhismomentumisp�mv�m�2�dg�(60.0kg)�(2)(0.3��2m)(9.80m�/s�2)�1.5�102kg�m/sdownb.Whatimpulseisneededtostopthedancer?F�t�m�v�m(vf�vi)Tostopthedancer,vf�0.Thus,F�t��mv2kg�m/supf��p��1.5�10c.Asthedancerlands,hiskneesbend,lengtheningthestoppingtimeto0.050s.Findtheaverageforceexertedonthedancer’sbody.F�t�m�v�m�2�dgm�2�dgso,F����t(60.0kg)�(2)(0.3�2m)(9�.80m�/s�2)�����0.050s�3.0�103Nd.Comparethestoppingforcewithhisweight.F2)�5.98�102Ng�mg�(60.0kg)(9.80m/sTheforceisaboutfivetimestheweight.ThinkingCriticallypage25490.ApplyConceptsA92-kgfullback,runningat5.0m/s,attemptstodivedirectlyCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.acrossthegoallineforatouchdown.Justashereachestheline,heismethead-oninmidairbytwo75-kglinebackers,bothmovinginthedirectionoppositethefull-back.Oneismovingat2.0m/sandtheotherat4.0m/s.Theyallbecomeentan-gledasonemass.a.Sketchtheevent,identifyingthe“before”and“after”situations.Before:mA�92kgmB�75kgmC�75kgvAi�5.0m/svBi��2.0m/svCi��4.0m/sAfter:mA�92kgmB�75kgmC�75kgvf�?218SolutionsManualPhysics:PrinciplesandProblems
222Chapter9continuedBeforeAftervAivBivCivf+xb.Whatisthevelocityofthefootballplayersafterthecollision?pAi�pBi�pCi�pAf�pBf�pCfmAvAi�mBvBi�mCvCi�mAvAf�mBvBf�mCvCf�(mA�mB�mC)vfmv���AvAi�mBvBi�mCivCif�mA�mB�mC(92kg)(5.0m/s)�(75kg)(�2.0m/s)�(75kg)(�4.0m/s)��������92kg�75kg�75kg�0.041m/sc.Doesthefullbackscoreatouchdown?Yes.Thevelocityispositive,sothefootballcrossesthegoallineforatouchdown.91.AnalyzeandConcludeAstudent,holdingabicyclewheelwithitsaxisvertical,sitsonastoolthatcanrotatewithoutfriction.Sheusesherhandtogetthewheelspinning.Wouldyouexpectthestudentandstooltoturn?Ifso,inwhichdirection?Explain.Thestudentandthestoolwouldspinslowlyinthedirectionoppositetothatofthewheel.Withoutfrictiontherearenoexternaltorques.Thus,theangularmomentumofthesystemisnotchanged.Theangularmomentumofthestudentandstoolmustbeequalandoppositetotheangularmomentumofthespinningwheel.92.AnalyzeandConcludeTwoballsduringacollisionareshowninFigure9-22,whichisdrawntoscale.Theballsenterfromtheleft,collide,andthenbounceaway.Theheavierball,atthebottomofthediagram,hasamassof0.600kg,andtheotherhasamassof0.400kg.Usingavectordiagram,determinewhethermomentumisconservedinthiscollision.Explainanydifferenceinthemomentumofthesystembeforeandafterthecollision.■Figure9-22Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Dottedlinesshowthatthechangesofmomentumforeachballareequalandopposite:�(mAvA)��(mBvB).Becausethemasseshavea3:2ratio,a2:3ratioofvelocitychangeswillcompensate.Physics:PrinciplesandProblemsSolutionsManual219
223Chapter9continued�vB1Systemsarebeingdevelopedthatwilladjusttherateatwhichgasesfilltheairbagstomatchthesizeoftheperson.mB�0.400kg�vBvvB2B1CumulativeReviewpage254v95.A0.72-kgballisswungverticallyfromavA1A20.60-mstringinuniformcircularmotionat�vAaspeedof3.3m/s.Whatisthetensioninthecordatthetopoftheball’smotion?�vA1mA�0.600kg(Chapter6)WritinginPhysicsThetensionisthegravitationalforcepage254minusthecentripetalforce.93.HowcanhighwaybarriersbedesignedtoFT�Fg�Fcbemoreeffectiveinsavingpeople’slives?mv2v2Researchthisissueanddescribehow�mg���m�g���rrimpulseandchangeinmomentumcanbeusedtoanalyzebarrierdesigns.(3.3m/s)2�(0.72kg)�(9.80m/s2)����0.60mThechangeinacar’smomentumdoes��6.0Nnotdependonhowitisbroughttoastop.Thus,theimpulsealsodoesnot96.Youwishtolaunchasatellitethatwillchange.Toreducetheforce,thetimeremainabovethesamespotonEarth’ssur-overwhichacarisstoppedmustbeface.Thismeansthesatellitemusthaveaincreased.Usingbarriersthatcanperiodofexactlyoneday.Calculatetheextendthetimeittakestostopacarradiusofthecircularorbitthissatellitewillreducetheforce.Flexible,plasticmusthave.Hint:TheMoonalsocirclesEarthcontainersfilledwithsandoftenareandboththeMoonandthesatellitewillobeyused.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Kepler’sthirdlaw.TheMoonis3.9�108mfromEarthanditsperiodis27.33days.94.Whileairbagssavemanylives,theyalso(Chapter7)havecausedinjuriesandevendeath.ResearchtheargumentsandresponsesofTs2rs3�������automobilemakerstothisstatement.TmrmDeterminewhethertheproblemsinvolve21T���s33impulseandmomentumorotherissues.sors���T�rm�mTherearetwowaysanairbagreduces2�1injury.First,anairbagextendsthetime����1.000�day�(3.9�108m)3�327.33daysoverwhichtheimpulseacts,therebyreducingtheforce.Second,anairbag�4.3�107mspreadstheforceoveralargerarea,therebyreducingthepressure.Thus,97.Aropeiswrappedaroundadrumthatistheinjuriesduetoforcesfromsmall0.600mindiameter.Amachinepullswithobjectsarereduced.Thedangersofairaconstant40.0Nforceforatotalof2.00s.bagsmostlycenteronthefactthatairInthattime,5.00mofropeisunwound.bagsmustbeinflatedveryrapidly.TheFind�,�at2.00s,andI.(Chapter8)surfaceofanairbagcanapproachtheTheangularaccelerationistheratioofpassengeratspeedsofupto322km/hthelinearaccelerationofthedrum’s(200mph).Injuriescanoccurwhentheedgeanddrum’sradius.movingbagcollideswiththeperson.220SolutionsManualPhysics:PrinciplesandProblems
224Chapter9continueda����rThelinearaccelerationisfoundfromtheequationofmotion.12x��at22xa��2tThus,theangularaccelerationisa2x������2rrt(2)(5.00m)������0.60�0m�(2.00s)22�8.33rad/s2Attheendof2.00s,theangularvelocityis���t2xt��rt22x���rt(2)(5.00m)����0.600m����(2.00s)2�16.7rad/sThemomentofinertiais�I���Frsin�Fr2t2sin������2x2x���2�rt(40.0N)��0.60�0m�2(2.00s)2(sin90.0°)2����(2)(5.00m)�1.44kg�m2ChallengeProblempage244Yourfriendwasdrivingher1265-kgcarnorthonOakStreetwhenshewashitbya925-kgcompactcargoingwestonMapleStreet.Thecarsstucktogetherandslid23.1mat42°northofwest.Thespeedlimitonbothstreetsis22m/s(50mph).AssumethatmomentumwasconservedduringthecollisionandthataccelerationCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.wasconstantduringtheskid.Thecoefficientofkineticfrictionbetweenthetiresandthepavementis0.65.Physics:PrinciplesandProblemsSolutionsManual221
225Chapter9continued�y925kg�x42°1265kg1.Yourfriendclaimsthatshewasn’tspeeding,butthatthedriverofothercarwas.Howfastwasyourfrienddrivingbeforethecrash?Thevectordiagramprovidesamomentumequationforthefriend’scar.pCi�pfsin42°Thefriend’sinitialvelocity,then,isp(mv�Ci���C�mD)vfsin42°Ci��mmCCWecanfindvffirstbyfindingtheaccelerationandtimeoftheskid.TheaccelerationisF�Fg�(mC�mD)ga���������gmmmC�mDThetimecanbederivedfromthedistanceequation.12d��at2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2d2dt�����������a�gThefinalvelocity,then,is2dv����2�d�gf�at��g���gUsingthis,wenowcanfindthefriend’sinitialvelocity.(mv���C�mD)vfsin42°Ci�mC(mC�mD)�2�d�gsin42°�����mC(1265kg�925kg)��(2)(23�.1m)(�0.65)(�9.80m�/s�2)�(sin42°)������1265kg�2.0�101m/s222SolutionsManualPhysics:PrinciplesandProblems
226Chapter9continued2.Howfastwastheothercarmovingbeforethecrash?Canyousupportyourfriend’scaseincourt?Fromthevectordiagram,themomentumequationfortheothercarispDi�pfcos42°�(mC�mD)vfcos42°�(mC�mD)�2�d�g(cos42°)Theothercar’sinitialvelocity,then,is,pv�DiDi�mD(mC�mD)�2�d�g(sin42°)�����mD(1265kg�925kg)��(2)(23�.1m)(�0.65)(�9.80m�/s�2)�(cos42°)������925kg�3.0�101m/sThefriendwasnotexceedingthe22m/sspeedlimit.Theothercarwasexceedingthespeedlimit.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual223
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228CHAPTEREnergy,Work,and10SimpleMachines3.Arockclimberwearsa7.5-kgbackpackPracticeProblemswhilescalingacliff.After30.0min,the10.1EnergyandWorkclimberis8.2mabovethestartingpoint.pages257–265a.Howmuchworkdoestheclimberdopage261onthebackpack?1.RefertoExampleProblem1tosolvetheW�Fdfollowingproblem.�mgda.Ifthehockeyplayerexertedtwiceas�(7.5kg)(9.80m/s2)(8.2m)muchforce,9.00N,onthepuck,how2J�6.0�10wouldthepuck’schangeinkineticb.Iftheclimberweighs645N,howmuchenergybeaffected?workdoesshedoliftingherselfandtheBecauseW�Fdand�KE�W,backpack?doublingtheforcewoulddoubleW�Fd�6.0�102Jthework,whichwoulddoublethechangeinkineticenergyto1.35J.�(645N)(8.2m)�6.0�102Jb.Iftheplayerexerteda9.00N-force,but�5.9�103Jthestickwasincontactwiththepuckc.Whatistheaveragepowerdevelopedbyforonlyhalfthedistance,0.075m,theclimber?whatwouldbethechangeinkinetic3W5.9�10J1minenergy?P������������t30.0min60sBecauseW�Fd,halvingthe�3.3Wdistancewouldcuttheworkinhalf,whichalsowouldcutthechangeinkineticenergyinhalf,to0.68J.page2624.IfthesailorinExampleProblem2pulled2.Together,twostudentsexertaforceof825Nwiththesameforce,andalongthesameinpushingacaradistanceof35m.distance,butatanangleof50.0°,howa.Howmuchworkdothestudentsdoonmuchworkwouldhedo?thecar?W�Fdcos�W�Fd�(825N)(35m)�(255N)(30.0m)(cos50.0°)�2.9�104J�4.92�103Jb.Iftheforcewasdoubled,howmuchworkwouldtheydopushingthecarthe5.Twopeopleliftaheavyboxadistanceofsamedistance?15m.Theyuseropes,eachofwhichmakesanangleof15°withthevertical.EachW�Fdpersonexertsaforceof225N.Howmuch�(2)(825N)(35m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.workdotheydo?�5.8�104JwhichistwiceasW�Fdcos�muchwork�(2)(225N)(15m)(cos15°)�6.5�103JPhysics:PrinciplesandProblemsSolutionsManual225
229Chapter10continued6.Anairplanepassengercarriesa215-Nsuit-W�Fdcaseupthestairs,adisplacementof4.20m�(25N)(275m)vertically,and4.60mhorizontally.3J�6.9�10a.Howmuchworkdoesthepassengerdo?b.HowmuchworkisdonebytheforceofSincegravityactsvertically,onlythegravityonthebike?verticaldisplacementneedstobeTheforceisdownward(�90°),andconsidered.thedisplacementis25°abovetheW�Fd�(215N)(4.20m)�903Jhorizontalor115°fromtheforce.b.ThesamepassengercarriesthesameW�Fdcos�suitcasebackdownthesamesetof�mgdcos�stairs.Howmuchworkdoesthe�(13kg)(9.80m/s2)(275m)passengerdonow?(cos115°)Forceisupward,butvertical��1.5�104Jdisplacementisdownward,soW�Fdcos�page264�(215N)(4.20m)(cos180.0°)9.Aboxthatweighs575Nisliftedadistance��903Jof20.0mstraightupbyacableattachedtoamotor.Thejobisdonein10.0s.Whatpower7.AropeisusedtopullametalboxadistanceisdevelopedbythemotorinWandkW?of15.0macrossthefloor.TheropeisheldWFd(575N)(20.0m)atanangleof46.0°withthefloor,andaP���������tt10.0sforceof628Nisappliedtotherope.How�1.15�103W�1.15kWmuchworkdoestheforceontheropedo?W�Fdcos�10.Youpushawheelbarrowadistanceof�(628N)(15.0m)(cos46.0°)60.0mataconstantspeedfor25.0s,by�6.54�103Jexertinga145-Nforcehorizontally.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Whatpowerdoyoudevelop?8.AbicycleriderpushesabicyclethathasaWFd(145N)(60.0m)massof13kgupasteephill.TheinclineisP����������348Wtt25.0s25°andtheroadis275mlong,asshownb.IfyoumovethewheelbarrowtwiceasinFigure10-4.Theriderpushesthebikefast,howmuchpowerisdeveloped?paralleltotheroadwithaforceof25N.tishalved,soPisdoubledto696W.11.Whatpowerdoesapumpdeveloptolift5m35Lofwaterperminutefromadepthof27110m?(1Lofwaterhasamassof1.00kg.)WmgdmP�����������gdtttm25Nwhere���(35L/min)(1.00kg/L)25°tThus,■Figure10-4(Nottoscale)a.HowmuchworkdoestheriderdoonP���m��tgdthebike?�(35L/min)(1.00kg/L)(9.80m/s2)Forceanddisplacementareinthesamedirection.(110m)(1min/60s)�0.63kW226SolutionsManualPhysics:PrinciplesandProblems
230Chapter10continued12.Anelectricmotordevelops65kWofpower1���(15m)(210.0N�40.0N)asitliftsaloadedelevator17.5min35s.2Howmuchforcedoesthemotorexert?�1.9�103JWFdP������ttPt(65�103W)(35s)210.0F�������d17.5m�1.3�105NForce(N)40.013.Awinchdesignedtobemountedona0truck,asshowninFigure10-7,isadver-15tisedasbeingabletoexerta6.8�103-NDisplacement(m)forceandtodevelopapowerof0.30kW.Howlongwouldittakethetruckandthewinchtopullanobject15m?SectionReview10.1EnergyandWorkpages257–265page26515.WorkMurimipushesa20-kgmass10macrossafloorwithahorizontalforceof80N.CalculatetheamountofworkdonebyMurimi.W�Fd�(80N)(10m)�8�102JThemassisnotimportanttothisproblem.■Figure10-716.WorkAmoverloadsa185-kgrefrigeratorWFdintoamovingvanbypushingitupaP������tt10.0-m,friction-freerampatanangleofFdinclinationof11.0°.Howmuchworkist���Pdonebythemover?(6.8�103N)(15m)y�(10.0m)(sin11.0°)�����340s(0.30�103W)�1.91m�5.7minW�Fd�mgdsin��(185kg)(9.80m/s2)(10.0m)(sin11.0°)14.Yourcarhasstalledandyouneedtopushit.Younoticeasthecargetsgoingthatyou�3.46�103Jneedlessandlessforcetokeepitgoing.Supposethatforthefirst15m,yourforce17.WorkandPowerDoestheworkrequireddecreasedataconstantratefrom210.0Ntotoliftabooktoahighshelfdependon40.0N.Howmuchworkdidyoudoonthehowfastyouraiseit?Doesthepowercar?Drawaforce-displacementgraphtorequiredtoliftthebookdependonhowCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.representtheworkdoneduringthisperiod.fastyouraiseit?Explain.TheworkdoneistheareaoftheNo,workisnotafunctionoftime.trapezoidunderthesolidline:However,powerisafunctionoftime,sothepowerrequiredtoliftthebookdoes1W���d(F21�F2)dependonhowfastyouraiseit.Physics:PrinciplesandProblemsSolutionsManual227
231Chapter10continued18.PowerAnelevatorliftsatotalmassof23.CriticalThinkingExplainhowtofindthe1.1�103kgadistanceof40.0min12.5s.changeinenergyofasystemifthreeagentsHowmuchpowerdoestheelevatorgenerate?exertforcesonthesystematonce.WFdmgdSinceworkisthechangeinkineticP���������tttenergy,calculatetheworkdonebyeach(1.1�103kg)(9.80m/s2)(40.0m)force.Theworkcanbepositive,nega-�����12.5stive,orzero,dependingontherelative4Wanglesoftheforceanddisplacementof�3.4�10theobject.Thesumofthethreeworksisthechangeinenergyofthesystem.19.WorkA0.180-kgballfalls2.5m.Howmuchworkdoestheforceofgravitydoontheball?PracticeProblemsW�Fgd�mgd10.2Machines�(0.180kg)(9.80m/s2)(2.5m)pages266–273�4.4Jpage27224.IfthegearradiusinthebicycleinExample20.MassAforkliftraisesabox1.2mandProblem4isdoubled,whiletheforceexerteddoes7.0kJofworkonit.Whatisthemassonthechainandthedistancethewheelrimofthebox?movesremainthesame,whatquantitiesW�Fd�mgdchange,andbyhowmuch?W7.0�103Jrsom�������e8.00cmgd(9.80m/s2)(1.2m)IMA�������0.225(doubled)r35.6cmr�6.0�102kge95.0MA�����IMA���(0.225)10010021.WorkYouandafriendeachcarryidentical�0.214(doubled)boxesfromthefirstfloorofabuildingtoaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.roomlocatedonthesecondfloor,fartherFrMA���soFdownthehall.YouchoosetocarrytheboxFr�(MA)(Fe)efirstupthestairs,andthendownthehallto�(0.214)(155N)theroom.Yourfriendcarriesitdownthehallonthefirstfloor,thenupadifferentstairwell�33.2Ntothesecondfloor.Whodoesmorework?deIMA���Bothdothesameamountofwork.drOnlytheheightliftedandtheverticalsodforceexertedcount.e�(IMA)(dr)�(0.225)(14.0cm)22.WorkandKineticEnergyIfthework�3.15cmdoneonanobjectdoublesitskineticenergy,doesitdoubleitsvelocity?Ifnot,25.Asledgehammerisusedtodriveawedgebywhatratiodoesitchangethevelocity?intoalogtosplitit.Whenthewedgeisdri-Kineticenergyisproportionaltotheven0.20mintothelog,thelogisseparatedsquareofthevelocity,sodoublingtheadistanceof5.0cm.Aforceof1.7�104Nenergydoublesthesquareoftheveloc-isneededtosplitthelog,andthesledge-ity.Thevelocityincreasesbyafactorofhammerexertsaforceof1.1�104N.thesquarerootof2,or1.4.a.WhatistheIMAofthewedge?de(0.20m)IMA�������4.0d(0.050m)r228SolutionsManualPhysics:PrinciplesandProblems
232Chapter10continuedb.WhatistheMAofthewedge?27.Youexertaforceof225NonalevertoFraisea1.25�103-NrockadistanceofrMA���13cm.IftheefficiencyoftheleverisFe88.7percent,howfardidyoumoveyour(1.7�104N)����1.5endofthelever?(1.1�104N)Woc.Calculatetheefficiencyofthewedgeasefficiency��W��100iamachine.FrdrMA����100e����100FdIMAee��1.�5�100�38%Frdr(100)4.0Sode���Fe(efficiency)26.Aworkerusesapulleysystemtoraise(1.25�103N)(0.13m)(100)�����a24.0-kgcarton16.5m,asshownin(225N)(88.7)Figure10-14.Aforceof129Nisexerted,�0.81mandtheropeispulled33.0m.28.Awinchhasacrankwitha45-cmradius.Aropeiswrappedaroundadrumwitha7.5-cmradius.Onerevolutionofthecrankturnsthedrumonerevolution.33.0ma.Whatistheidealmechanicaladvantage24.0kgofthismachine?Compareeffortandresistancedistancesfor1rev:16.5mde(2�)45cmIMA�������6.0129Ndr(2�)7.5cmb.If,duetofriction,themachineisonly■Figure10-1475percentefficient,howmuchforcea.WhatistheMAofthepulleysystem?wouldhavetobeexertedonthehandleFrmgofthecranktoexert750NofforceonMA������therope?FFeeMA(24.0kg)(9.80m/s2)efficiency������100����IMA129NFr�1.82����100(F(IMA)e)b.Whatistheefficiencyofthesystem?(Fr)(100)MAsoF���efficiency������100e�(efficiency)(IMA)IMA(750N)(100)(MA)(100)������(75)(6.0)de��dr�1.7�102NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(MA)(d���r)(100)de(1.82)(16.5m)(100)����33.0m�91.0%Physics:PrinciplesandProblemsSolutionsManual229
233Chapter10continuedde(3)(2�r)SectionReviewIMA������d2�rr10.2Machines(3)(2�)(45cm)pages266–273���(2�)(7.5cm)page273�1829.SimpleMachinesClassifythetoolsbelowasalever,awheelandaxle,aninclined32.EfficiencySupposeyouincreasetheeffi-plane,awedge,orapulley.ciencyofasimplemachine.DotheMAanda.screwdriverIMAincrease,decrease,orremainthesame?wheelandaxleEitherMAincreaseswhileIMAremainsb.pliersthesame,orIMAdecreaseswhileMAremainsthesame,orMAincreasesleverwhileIMAdecreases.c.chiselwedge33.CriticalThinkingThemechanicaladvan-d.nailpullertageofamulti-gearbicycleischangedbymovingthechaintoasuitablereargear.levera.Tostartout,youmustacceleratethe30.IMAAworkeristestingamultiplepulleybicycle,soyouwanttohavethebicyclesystemtoestimatetheheaviestobjectthatexertthegreatestpossibleforce.Shouldhecouldlift.Thelargestdownwardforceheyouchooseasmallorlargegear?couldexertisequaltohisweight,875N.rgearlarge,toincreaseIMA���Whentheworkermovestherope1.5m,therwheelobjectmoves0.25m.Whatistheheaviestb.Asyoureachyourtravelingspeed,youobjectthathecouldlift?wanttorotatethepedalsasfewtimesasFrpossible.ShouldyouchooseasmallorMA���Felargegear?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.soFSmall,becauselesschaintravel,r�(MA)(Fe)hencefewpedalrevolutions,willbeAssumingtheefficiencyis100%,requiredperwheelrevolution.dec.ManybicyclesalsoletyouchoosetheMA�IMA���d��(Fe)rsizeofthefrontgear.Ifyouwanteven(1.5m)moreforcetoacceleratewhileclimbing���(875N)(0.25m)ahill,wouldyoumovetoalargerorsmallerfrontgear?�5.2�103Nsmaller,toincreasepedal-frontgear31.CompoundMachinesAwinchhasacrankIMAbecauseona45-cmarmthatturnsadrumwitharpedalIMA���7.5-cmradiusthroughasetofgears.Ittakesrfrontgearthreerevolutionsofthecranktorotatethedrumthroughonerevolution.WhatistheIMAofthiscompoundmachine?TheIMAofthesystemistheproductoftheIMAofeachmachine.Forthecrankanddrum,theratioofdistancesis2�(45cm)���6.0.2�(7.5cm)230SolutionsManualPhysics:PrinciplesandProblems
234Chapter10continued39.WhatisawattequivalenttointermsofChapterAssessmentkilograms,meters,andseconds?(10.1)ConceptMappingW�J/spage278�N�m/s34.Createaconceptmapusingthefollowing�(kg�m/s2)�m/sterms:force,displacement,directionofmotion,�kg�m2/s3work,changeinkineticenergy.40.IsitpossibletogetmoreworkoutofaDirectionForceDisplacementmachinethanyouputintoit?(10.2)ofmotionno,e�100%Work41.Explainhowthepedalsofabicycleareasimplemachine.(10.2)PedalstransferforcefromtheridertoChangeinthebikethroughawheelandaxle.kineticenergyApplyingConceptsMasteringConceptspage278page27842.Whichrequiresmorework,carrying35.Inwhatunitsisworkmeasured?(10.1)a420-Nbackpackupa200-m-highhilljoulesorcarryinga210-Nbackpackupa400-m-highhill?Why?36.SupposeasatelliterevolvesaroundEarthinEachrequiresthesameamountofacircularorbit.DoesEarth’sgravitydoanyworkbecauseforcetimesdistanceisworkonthesatellite?(10.1)thesame.No,theforceofgravityisdirectedtowardEarthandisperpendiculartothe43.LiftingYouslowlyliftaboxofbooksfromdirectionofdisplacementofthesatellite.thefloorandputitonatable.Earth’sgravityexertsaforce,magnitudemg,downward,and37.Anobjectslidesatconstantspeedonayouexertaforce,magnitudemg,upward.frictionlesssurface.WhatforcesactontheThetwoforceshaveequalmagnitudesandobject?Whatworkisdonebyeachforce?oppositedirections.Itappearsthatnowork(10.1)isdone,butyouknowthatyoudidwork.Explainwhatworkwasdone.Onlygravityandanupward,normalforceactontheobject.NoworkisYoudopositiveworkontheboxdonebecausethedisplacementisbecausetheforceandmotionareintheperpendiculartotheseforces.Theresamedirection.Gravitydoesnegativeisnoforceinthedirectionofdisplace-workontheboxbecausetheforceofmentbecausetheobjectisslidingatagravityisoppositetothedirectionofconstantspeed.motion.Theworkdonebyyouandbygravityareseparateanddonotcancel38.Defineworkandpower.(10.1)eachother.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Workistheproductofforceandthe44.Youhaveanafter-schooljobcarryingcar-distanceoverwhichanobjectismovedtonsofnewcopypaperupaflightofstairs,inthedirectionoftheforce.Powerisandthencarryingrecycledpaperbackdownthetimerateatwhichworkisdone.thestairs.ThemassofthepaperdoesnotPhysics:PrinciplesandProblemsSolutionsManual231
235Chapter10continuedchange.Yourphysicsteachersaysthatyou48.Howcanyouincreasetheidealmechanicaldonotworkallday,soyoushouldnotbeadvantageofamachine?paid.InwhatsenseisthephysicsteacherIncreasetheratioofde/drtoincreasecorrect?WhatarrangementofpaymentstheIMAofamachine.mightyoumaketoensurethatyouareproperlycompensated?49.WedgeHowcanyouincreasethemechani-Thenetworkiszero.Carryingthecartoncaladvantageofawedgewithoutchangingupstairsrequirespositivework;carryingitsidealmechanicaladvantage?itbackdownisnegativework.TheworkReducefrictionasmuchaspossibletodoneinbothcasesisequalandoppo-reducetheresistanceforce.sitebecausethedistancesareequalandopposite.Thestudentmightarrangethe50.OrbitsExplainwhyaplanetorbitingtheSunpaymentsonthebasisofthetimeitdoesnotviolatethework-energytheorem.takestocarrypaper,whetheruporAssumingacircularorbit,theforcedown,notonthebasisofworkdone.duetogravityisperpendiculartothedirectionofmotion.Thismeansthe45.Youcarrythecartonsofcopypaperdownworkdoneiszero.Hence,thereisnothestairs,andthenalonga15-m-longchangeinkineticenergyoftheplanet,hallway.Areyouworkingnow?Explain.soitdoesnotspeeduporslowdown.No,theforceontheboxisupandtheThisistrueforacircularorbit.displacementisdownthehall.Theyareperpendicularandnoworkisdone.51.ClawHammerAclawhammerisusedtopullanailfromapieceofwood,asshown46.ClimbingStairsTwopeopleofthesameinFigure10-16.Whereshouldyouplacemassclimbthesameflightofstairs.Theyourhandonthehandleandwhereshouldfirstpersonclimbsthestairsin25s;thethenailbelocatedintheclawtomakethesecondpersondoessoin35s.effortforceassmallaspossible?a.Whichpersondoesmorework?ExplainCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.youranswer.Bothpeoplearedoingthesameamountofworkbecausetheybothareclimbingthesameflightofstairsandtheyhavethesamemass.b.Whichpersonproducesmorepower?Explainyouranswer.Thepersonwhoclimbsin25s■Figure10-16expendsmorepower,aslesstimeisYourhandshouldbeasfarfromtheneededtocoverthedistance.headaspossibletomakedeaslargeaspossible.Thenailshouldbeascloseto47.ShowthatpowerdeliveredcanbewrittenastheheadaspossibletomakedP�Fvcos�.rassmallaspossible.WP���,butW�Fdcos�tFdcos�so,P���tdbecausev���,tP�Fvcos�232SolutionsManualPhysics:PrinciplesandProblems
236Chapter10continuedMasteringProblemsWFdP������tt10.1EnergyandWork(15.0N)(2.51m)pages278–280���30.0sLevel1�126W52.Thethirdfloorofahouseis8mabovestreetlevel.Howmuchworkisneededtomovea58.Astudentlibrarianliftsa2.2-kgbookfrom150-kgrefrigeratortothethirdfloor?thefloortoaheightof1.25m.HecarriestheW�Fd�mgdbook8.0mtothestacksandplacesthebook�(150kg)(9.80m/s2)(8m)onashelfthatis0.35mabovethefloor.Howmuchworkdoeshedoonthebook?�1�104JOnlythenetverticaldisplacementcounts.53.Halokedoes176Jofworkliftinghimself0.300m.WhatisHaloke’smass?W�Fd�mgdW�Fd�mgd;therefore,�(2.2kg)(9.80m/s2)(0.35m)W176J�7.5Jm�������gd(9.80m/s2)(0.300m)�59.9kg59.Aforceof300.0Nisusedtopusha145-kgmass30.0mhorizontallyin3.00s.54.FootballAfterscoringatouchdown,ana.Calculatetheworkdoneonthemass.84.0-kgwidereceivercelebratesbyleapingW�Fd�(300.0N)(30.0m)1.20mofftheground.Howmuchworkwasdonebythewidereceiverinthe�9.00�103Jcelebration?�9.00kJW�Fd�mgdb.Calculatethepowerdeveloped.�(84.0kg)(9.80m/s2)(1.20m)W9.00�103JP������t3.00s�988J�3.00�103W55.Tug-of-WarDuringatug-of-war,teamA�3.00kWdoes2.20�105JofworkinpullingteamB8.00m.WhatforcewasteamAexerting?Level2W�Fd,so60.WagonAwagonispulledbyaforceofW2.20�105J4N38.0NexertedonthehandleatanangleofF�������2.75�10d8.00m42.0°withthehorizontal.Ifthewagonispulledinacircleofradius25.0m,how56.Tokeepacartravelingataconstantvelocity,muchworkisdone?a551-NforceisneededtobalancefrictionalW�Fdcos�forces.Howmuchworkisdoneagainstfric-�(F)(2�r)cos�tionbythecarasittravelsfromColumbustoCincinnati,adistanceof161km?�(38.0N)(2�)(25.0m)(cos42.0°)W�Fd�(551N)(1.61�105m)�4.44�103JCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�8.87�107J61.LawnMowerShaniispushingalawnmowerwithaforceof88.0Nalongahan-57.CyclingAcyclistexertsaforceof15.0Nasdlethatmakesanangleof41.0°withtheheridesabike251min30.0s.Howmuchhorizontal.Howmuchworkisdonebypowerdoesthecyclistdevelop?Physics:PrinciplesandProblemsSolutionsManual233
237Chapter10continuedShaniinmovingthelawnmower1.2km(225N)(1.15m)���tomowtheyard?sin30.0°W�Fdcos��518J�(88.0N)(1.2�103m)(cos41.0°)65.PianoA4.2�103-Npianoistobeslidupa�8.0�104J3.5-mfrictionlessplankataconstantspeed.Theplankmakesanangleof30.0°withthe62.A17.0-kgcrateistobepulledadistanceofhorizontal.Calculatetheworkdonebythe20.0m,requiring1210Jofworktobepersonslidingthepianouptheplank.done.IfthejobisdonebyattachingaropeTheforceparalleltotheplaneisgivenbyandpullingwithaforceof75.0N,atwhatFangleistheropeheld?��Fsin�soW�FW�Fdcos��d�Fdsin�W�(4200N)(3.5m)(sin30.0°)�1W��cos��Fd���7.4�103J�11210J�cos��(75.0N)(�20.0m)�66.SledDiegopullsa4.5-kgsledacrosslevelsnowwithaforceof225Nonaropethat�36.2°is35.0°abovethehorizontal,asshowninFigure10-18.Ifthesledmovesadistance63.LawnTractorA120-kglawntractor,of65.3m,howmuchworkdoesDiegodo?showninFigure10-17,goesupa21°inclinethatis12.0mlongin2.5s.CalculatethepowerthatisdevelopedN25bythetractor.2kg4.5kg35.0°120.0mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc..012■Figure10-18W�Fdcos�21°�(225N)(65.3m)(cos35.0°)■Figure10-174J�1.20�10WFdsin�mgdsin�P���������ttt67.EscalatorSau-Lanhasamassof52kg.(120kg)(9.80m/s2)(12.0m)(sin21°)SheridesuptheescalatoratOceanParkin������HongKong.Thisistheworld’slongest2.5sescalator,withalengthof227mandan�2.0�103W�2.0kWaverageinclinationof31°.HowmuchworkdoestheescalatordoonSau-Lan?64.Youslideacrateuparampatanangleof30.0°byexertinga225-NforceparalleltoW�Fdsin��mgdsin�theramp.Thecratemovesataconstant�(52kg)(9.80m/s2)(227m)(sin31°)speed.Thecoefficientoffrictionis0.28.�6.0�104JHowmuchworkdidyoudoonthecrateasitwasraisedaverticaldistanceof1.15m?68.LawnRollerAlawnrollerispushedFanddareparallelsoacrossalawnbyaforceof115Nalonghthedirectionofthehandle,whichis22.5°W�Fd�F����sin�234SolutionsManualPhysics:PrinciplesandProblems
238Chapter10continuedabovethehorizontal.If64.6Wofpowerisdevelopedfor90.0s,whatdistanceistherollerpushed?WFdcos�kgP������so,.0tt60m1.0m2.0Ptd���NFcos�0.040(64.6W)(90.0s)����(115N)(cos22.5°)■Figure10-19�54.7ma.HowmuchworkdoesMaricruzdoinslidingthecrateuptheramp?69.Johnpushesacrateacrossthefloorofafactorywithahorizontalforce.Therough-W�Fd�(400.0N)(2.0m)�8.0�102Jnessofthefloorchanges,andJohnmustb.Howmuchworkwouldbedoneifexertaforceof20Nfor5m,then35NforMaricruzsimplyliftedthecratestraight12m,andthen10Nfor8m.upfromthefloortotheplatform?a.DrawagraphofforceasafunctionofW�Fd�mgddistance.�(60.0kg)(9.80m/s2)(1.0m)40�5.9�102J302071.BoatEngineAnenginemovesaboatForce(N)throughthewaterataconstantspeedof1015m/s.Theenginemustexertaforce0510152025of6.0kNtobalancetheforcethattheDisplacement(m)waterexertsagainstthehull.Whatpowerdoestheenginedevelop?b.FindtheworkJohndoespushingtheWFdP�������Fvcrate.ttW�F�(6.0�103N)(15m/s)1d1�F2d2�F3d3�(20N)(5m)�(35N)(12m)��9.0�104W�9.0�101kW(10N)(8m)Level3�600J72.InFigure10-20,themagnitudeoftheforcenecessarytostretchaspringisplotted70.Maricruzslidesa60.0-kgcrateupanagainstthedistancethespringisstretched.inclinedrampthatis2.0-mlongandattachedtoaplatform1.0mabovefloorlevel,asshowninFigure10-19.A400.0-N8.00force,paralleltotheramp,isneededtoslidethecrateuptherampataconstant6.00speed.4.00Force(N)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2.000.000.100.200.30■Figure10-20Physics:PrinciplesandProblemsSolutionsManual235
239Chapter10continueda.Calculatetheslopeofthegraph,k,and74.Aworkerpushesacrateweighing93NupshowthatF�kd,wherek�25N/m.aninclinedplane.Theworkerpushesthe�y5.00N�0.00Ncratehorizontally,paralleltotheground,ask�������x0.20m�0.00millustratedinFigure10-21.F1�kd1Letd1�0.20m85NFromthegraph,Fm3.0m1is5.00N..05F1Sok���d14.0m5.00N����25N/m0.20m93Nb.Findtheamountofworkdonein■Figure10-21stretchingthespringfrom0.00mtoa.Theworkerexertsaforceof85N.0.20mbycalculatingtheareaunderHowmuchworkdoeshedo?thegraphfrom0.00mto0.20m.Displacementindirectionofforce1A���(base)(height)is4.0m,21soW�Fd�(85N)(4.0m)�����(0.20m)(5.00N)2�3.4�102J�0.50Jb.Howmuchworkisdonebygravity?c.Showthattheanswertopartb(Becarefulwiththesignsyouuse.)canbecalculatedusingtheformula1DisplacementindirectionofforceW���kd2,whereWisthework,2is�3.0m,k�25N/m(theslopeofthegraph),soW�Fd�(93N)(�3.0m)anddisthedistancethespringisstretched(0.20m).��2.8�102JCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.Thecoefficientoffrictionis��0.20.W�1�kd2��1�2�2�2�(25N/m)(0.20m)Howmuchworkisdonebyfriction?(Becarefulwiththesignsyouuse.)�0.50JW��FNd��(Fyou,��Fg,�)d73.UsethegraphinFigure10-20tofindthe�0.20(85N)(sin�)�workneededtostretchthespringfrom0.12mto0.28m.(93N)(cos�)(�5.0m)Addtheareasofthetriangleand3.0�0.20(85N)�����rectangle.Theareaofthetriangleis:5.0�1�bh��1�(0.28m�0.12m)(7.00N�3.00N)4.022(93N)��5.�0�(�5.0m)�0.32J��1.3�102J(workdoneagainstTheareaoftherectangleis:friction)bh�(0.28m�0.12m)(3.00N�0.00N)75.OilPumpIn35.0s,apumpdelivers�0.48J0.550m3ofoilintobarrelsonaplatformTotalworkis0.32J�0.48J�0.80J25.0mabovetheintakepipe.Theoil’sdensityis0.820g/cm3.236SolutionsManualPhysics:PrinciplesandProblems
240Chapter10continueda.Calculatetheworkdonebythepump.78.ThegraphinFigure10-22showstheforceTheworkdoneisanddisplacementofanobjectbeingpulled.W�Fgd�mgh�(volume)(density)gh�(0.550m3)(0.820g/cm3)��1k�g�40.01000g(1.00�106cm3/m3)(9.80m/s2)Force(N)20.0(25.0m)�1.10�105Jb.Calculatethepowerproducedbythe0.02.04.06.0pump.Displacement(m)W1.10�105J■Figure10-22P������t35.0sa.Calculatetheworkdonetopullthe�3.14�103W�3.14kWobject7.0m.76.ConveyorBeltA12.0-m-longconveyorFindtheareaunderthecurve(seebelt,inclinedat30.0°,isusedtograph):transportbundlesofnewspapersfromthe0.0to2.0m:mailroomuptothecargobaytobe11J��(20.0N)(2.0m)�2.0�10loadedontodeliverytrucks.Eachnewspa-2perhasamassof1.0kg,andthereare2.0mto3.0m:25newspapersperbundle.Determinethe1powerthattheconveyordevelopsifit��(30.0N)(1.0m)�(20N)(1.0m)�35J2delivers15bundlesperminute.3.0mto7.0m:WFdmgdP��t���t���t�(50.0N)(4.0m)�2.0�102J�(25newspapers)(15bundles/min)Totalwork:(1.0kg/newspaper)(9.80m/s2)2.0�101J�35J�2.0�102J(12.0m)(sin30.0°)(1min/60s)�2.6�102J�3.7�102Wb.Calculatethepowerthatwouldbedevelopediftheworkwasdonein2.0s.77.AcarisdrivenataconstantspeedofW2.6�102J2WP�������1.3�1076km/hdownaroad.Thecar’senginet2.0sdelivers48kWofpower.Calculatetheaverageforcethatisresistingthemotionofthecar.WFdP�������FvttPCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.soF���v48,000W���76km1000m1h������������1h1km3600s�2.3�103NPhysics:PrinciplesandProblemsSolutionsManual237
241Chapter10continued10.2Machines81.Apulleysystemliftsa1345-Nweightapages280–281distanceof0.975m.PaulpullstheropeaLevel1distanceof3.90m,exertingaforceof375N.79.PianoTakeshiraisesa1200-Npianoaa.Whatistheidealmechanicaladvantagedistanceof5.00musingasetofpulleys.ofthesystem?Hepullsin20.0mofrope.de3.90mIMA�������4.00a.HowmucheffortforcewouldTakeshid0.975mrapplyifthiswereanidealmachine?b.Whatisthemechanicaladvantage?Fdre�F���d�Fr1345NerMA������3.59F375NeFrdr(1200N)(5.00m)soF�����c.Howefficientisthesystem?e�d20.0meMA2Nefficiency����100�3.0�10IMAb.Whatforceisusedtobalancethefriction3.59����100forceiftheactualeffortis340N?4.00F�89.8%e�Ff�Fe,idealF2N82.Aforceof1.4Nisexertedthroughaf�Fe�Fe,ideal�340N�3.0�10distanceof40.0cmonaropeinapulley�40Nsystemtolifta0.50-kgmass10.0cm.c.Whatistheoutputwork?Calculatethefollowing.Wo�Frdr�(1200N)(5.00m)a.theMA�6.0�103JFmgrMA������d.Whatistheinputwork?FeFeWi�Fede�(340N)(20.0m)(0.50kg)(9.80m/s2)����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3J1.4N�6.8�10�3.5e.Whatisthemechanicaladvantage?b.theIMAFr1200NMA�������3.5dF340Ne40.0cmeIMA�������4.00d10.0cmr80.LeverBecausethereisverylittlefriction,c.theefficiencytheleverisanextremelyefficientsimpleMAmachine.Usinga90.0-percent-efficientefficiency����100IMAlever,whatinputworkisrequiredtoliftan3.518.0-kgmassthroughadistanceof0.50m?����100�88%4.00Woefficiency��W��10083.Astudentexertsaforceof250Nonalever,ithroughadistanceof1.6m,asheliftsa(Wo)(100)(mgd)(100)150-kgcrate.IftheefficiencyoftheleverisW�����i�efficiency90.090.0percent,howfaristhecratelifted?(18.0kg)(9.80m/s2)(0.50m)(100)F�������r90.0FMAee�90����100���100�98JIMAde��dFrrdr����100Fdee238SolutionsManualPhysics:PrinciplesandProblems
242Chapter10continuedeFedeeFedeb.WhatistheIMAoftheramp?so,d�����r�100F100mgdre18mIMA�������4.0(90.0)(250N)(1.6m)df4.5m����(100)(150kg)(9.80m/s2)c.WhataretherealMAandtheefficiency�0.24moftherampifaparallelforceof75Nisactuallyrequired?FrLevel2MA���F84.Whatworkisrequiredtolifta215-kgmasseadistanceof5.65m,usingamachinethatmg(25kg)(9.80m/s2)���������3.3is72.5percentefficient?F75NeWoMAe����100efficiency����100WIMAi3.3Frdr����100�82%����1004.0Wi86.BicycleLuisapedalsabicyclewithagearmgdrradiusof5.00cmandawheelradiusof����100Wi38.6cm,asshowninFigure10-24.Ifthemgdwheelrevolvesonce,whatisthelengthofrW���100i�ethechainthatwasused?(215kg)(9.80m/s2)(5.65m)(100)�����72.5�1.64�104J38.6cm85.TherampinFigure10-23is18mlongand4.5mhigh.5.00cm18mFA4.5m■Figure10-24d�2�r�2�(5.00cm)�31.4cmFg■Figure10-23Level3a.Whatforce,paralleltotheramp(FA),is87.CraneAmotorwithanefficiencyofrequiredtoslidea25-kgboxatconstant88percentoperatesacranewithanspeedtothetopoftherampiffrictionefficiencyof42percent.Ifthepowerisdisregarded?suppliedtothemotoris5.5kW,withW�Fgd�mghwhatconstantspeeddoesthecraneliftmgha410-kgcrateofmachineparts?soF�F��g�dTotalefficiency�(88%)(42%)�37%Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(25kg)(9.80m/s2)(4.5m)UsefulPower�(5.5kW)(37%)����18m�2.0kW�61N3W�2.0�10Physics:PrinciplesandProblemsSolutionsManual239
243Chapter10continuedWFddc.IfyoumovetheeffortsideoftheleverP�������F�����Fvttt12.0cm,howfaristheboxlifted?PP2.0�103Wde1v��F���m�g����2)���IMAcg(410kg)(9.80m/sdr2�0.50m/sde112.0cmd������2.0cmr2�IMA6.0c88.Acompoundmachineisconstructedbyattachingalevertoapulleysystem.MixedReviewConsideranidealcompoundmachinecon-pages281–282sistingofaleverwithanIMAof3.0andapulleysystemwithanIMAof2.0.Level189.RampsIsrahastogetapianoontoaa.ShowthattheIMAofthiscompound2.0-m-highplatform.Shecanuseamachineis6.0.3.0-m-longfrictionlessrampora4.0-m-longWi1�Wo1�Wi2�Wo2frictionlessramp.WhichrampshouldIsrauseWifshewantstodotheleastamountofwork?i1�Wo2Eitherramp:onlytheverticaldistanceFe1de1�Fr2dr2isimportant.IfIsrausedalongerramp,Forthecompoundmachineshewouldrequirelessforce.Theworkdonewouldbethesame.de1IMA��c�dr290.Brutus,achampionweightlifter,raisesde1de2240kgofweightsadistanceof2.35m.���IMA���IMAd1andd2a.HowmuchworkisdonebyBrutusr1r2dliftingtheweights?r1�de2W�Fd�mgdde1���dr1�de2�(IMA2)(dr2)�(240kg)(9.80m/s2)(2.35m)IMA1Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.d�5.5�103Je1�(IMA1)(IMA2)(dr2)b.HowmuchworkisdonebyBrutusde1���IMAholdingtheweightsabovehishead?dc�(IMA1)(IMA2)r2d�0,sonowork�(3.0)(2.0)�6.0c.HowmuchworkisdonebyBrutusb.Ifthecompoundmachineis60.0percentloweringthembacktotheground?efficient,howmucheffortmustbedisoppositeofmotioninparta,soappliedtothelevertolifta540-Nbox?Wisalsotheopposite,�5.5�103J.Frd.DoesBrutusdoworkifheletsgoofthe��MAFeweightsandtheyfallbacktotheground?e����100���100IMAIMANo.Heexertsnoforce,sohedoes(F)(100)rnowork,positiveornegative.���(F)(IMA)ee.IfBrutuscompletestheliftin2.5s,how(Fr)(100)muchpowerisdeveloped?soF��e�(e)(IMA)3JW5.5�10P�������2.2kW(540N)(100)t2.5s����150N(60.0)(6.0)240SolutionsManualPhysics:PrinciplesandProblems
244Chapter10continuedLevel293.Sallydoes11.4kJofworkdraggingawooden91.Ahorizontalforceof805Nisneededtocrate25.0macrossafloorataconstantdragacrateacrossahorizontalfloorwithaspeed.Theropemakesanangleof48.0°constantspeed.Youdragthecrateusingawiththehorizontal.ropeheldatanangleof32°.a.Howmuchforcedoestheropeexertona.Whatforcedoyouexertontherope?thecrate?Fx�Fcos�W�Fdcos�W11,400JFx805NsoF�������soF������dcos�(25.0m)(cos48.0°)cos�cos32°2N�681N�9.5�10b.Whatistheforceoffrictionactingonb.Howmuchworkdoyoudoonthecratethecrate?ifyoumoveit22m?ThecratemoveswithconstantW�Fxd�(805N)(22m)speed,sotheforceoffrictionequals�1.8�104Jthehorizontalcomponentofthec.Ifyoucompletethejobin8.0s,whatforceoftherope.powerisdeveloped?Ff�Fx�Fcos�W1.8�104J�(681N)(cos48.0°)P�������2.2kWt8.0s�456N,oppositetothedirectionofmotion92.DollyandRampAmover’sdollyisusedtotransportarefrigeratoruparampintoc.Whatworkisdonebythefloorthroughahouse.Therefrigeratorhasamassoftheforceoffrictionbetweenthefloor115kg.Therampis2.10mlongandrisesandthecrate?0.850m.ThemoverpullsthedollywithaForceanddisplacementareinforceof496Nuptheramp.Thedollyandoppositedirections,sorampconstituteamachine.W��Fd��(456N)(25.0m)a.Whatworkdoesthemoverdo?��1.14�104JWi�Fd�(496N)(2.10m)(Becausenonetforcesactonthe�1.04�103Jcrate,theworkdoneonthecratemustbeequalinmagnitudebutb.WhatistheworkdoneontheoppositeinsigntotheenergySallyrefrigeratorbythemachine?expands:�1.14�104J)d�heightraised�0.850mW94.SleddingAn845-Nsledispulledao�Fgd�mgddistanceof185m.Thetaskrequires�(115kg)(9.80m/s2)(0.850m)1.20�104Jofworkandisdonebypullingonaropewithaforceof125N.Atwhat�958Jangleistheropeheld?c.Whatistheefficiencyofthemachine?W�Fdcos�,soWo1.20�104Jefficiency����100��cos�1�W��1���W���cos��iFd(125N)(185m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��958�J�100�58.7°1.04�103J�92.1%Physics:PrinciplesandProblemsSolutionsManual241
245Chapter10continuedLevel3onlyoneboxatatime,mostoftheenergy95.Anelectricwinchpullsa875-Ncrateupawillgointoraisingyourownbody.The15°inclineat0.25m/s.Thecoefficientofpower(inwatts)thatyourbodycandevelopfrictionbetweenthecrateandinclineis0.45.overalongtimedependsonthemassthata.Whatpowerdoesthewinchdevelop?youcarry,asshowninFigure10-25.ThisisanexampleofapowercurvethatappliestoWorkisdoneonthecratebythemachinesaswellastopeople.Findthewinch,gravity,andfriction.Becausenumberofboxestocarryoneachtripthatthekineticenergyofthecratedoeswouldminimizethetimerequired.Whatnotchange,thesumofthethreetimewouldyouspenddoingthejob?Ignoreworksisequaltozero.thetimeneededtogobackdownthestairsTherefore,andtoliftandlowereachbox.Wwinch�Wfriction�WgravityPowerv.Massor,Pwinch�Pfriction�Pgravity25�FFdNdg������20tt15dd��FN��t���Fg��t��10Power(W)��FNv�Fgv5�(�F0g)(cos�)(v)�Fgv51015202530�(0.45)(875N)(cos15°)Mass(kg)■Figure10-25(0.25m/s)�Theworkhastobedonethesame,(875N)(0.25m/s)W�Fgd�mgd�3.1�102W�(150kg)(9.80m/s2)(12m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Ifthewinchis85percentefficient,whatistheelectricalpowerthatmust�1.76�104J.bedeliveredtothewinch?Fromthegraph,themaximumpowerisWoPo25Wat15kg.Sincethemassperboxise������WiPi150kg���5kg,thisrepresentsthree30boxesPoso,Pi��e�boxes.3.1�102WP��W�sot��W����tt0.85�3.6�102W1.76�104J���25WThinkingCritically�7.0�102spage282�12min96.AnalyzeandConcludeYouworkatastore,carryingboxestoastorageloftthatis12m97.ApplyConceptsAsprinterofmass75kgabovetheground.Youhave30boxeswitharunsthe50.0-mdashin8.50s.Assumethattotalmassof150kgthatmustbemovedasthesprinter’saccelerationisconstantquicklyaspossible,soyouconsidercarryingthroughouttherace.morethanoneupatatime.Ifyoutrytoa.Whatistheaveragepowerofthemovetoomanyatonce,youknowthatyousprinteroverthe50.0m?willgoveryslowly,restingoften.Ifyoucarry242SolutionsManualPhysics:PrinciplesandProblems
246Chapter10continuedAssumeconstantacceleration,Finalvelocity:thereforeconstantforcevf�vi�at12d�di�vit��2�atvi�0sobutdi�vi�0vf�at�a(t1)2dm��2��dWFdmadtTherefore,P�����������tttt1d��at2�at2md2(2)(75kg)(50.0m)f�211t2������t3(8.50s)31�a���t2�t2W211t2��6.1�10db.Whatisthemaximumpowergeneratedfa����1�t2�tbythesprinter?211t2Powerincreaseslinearlyfromzero,50.0msincethevelocityincreaseslinearly������1��(1.00s)2�(1.00s)(7.50s)asshownby2WFddP��t���t��F��t���Fv.�6.25m/s2ThereforeForthefirstsecond:P3Wd��1�at2��1�2)(1.00s)2max�2Pave�1.2�10��(6.25m/s22c.Makeaquantitativegraphofpower�3.12mversustimefortheentirerace.FromProblem97,madP���t1.2x103(75kg)(6.25m/s2)(3.12m)Power(W)Pave�����1.00s�1.5�103W08.50Time(s)b.Whatisthemaximumpowerthatthesprinternowgenerates?98.ApplyConceptsThesprinterintheP3Wmax�2Pave�3.0�10previousproblemrunsthe50.0-mdashinthesametime,8.50s.However,thisWritinginPhysicstimethesprinteracceleratesinthefirstpage282secondandrunstherestoftheraceata99.Justasabicycleisacompoundmachine,soconstantvelocity.isanautomobile.Findtheefficienciesofa.Calculatetheaveragepowerproducedthecomponentpartsofthepowertrainforthatfirstsecond.(engine,transmission,wheels,andtires).Distancefirstsecond�ExplorepossibleimprovementsineachofDistancerestofrace�50.0mtheseefficiencies.12Theoverallefficiencyis15–30percent.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.df�di�vit���at2Thetransmission’sefficiencyisaboutd90percent.Rollingfrictioninthetiresisi�vi�0soabout1percent(ratioofpushingforced�1�a(t2�vf�21)f(t2)�50.0mtoweightmoved).Thelargestgainispossibleintheengine.Physics:PrinciplesandProblemsSolutionsManual243
247Chapter10continued100.Thetermsforce,work,power,andenergy12d��gtfy�diy�viyt�2oftenmeanthesamethingineverydayuse.Obtainexamplesfromadvertisements,diy�viy�0printmedia,radio,andtelevisionthat12illustratemeaningsforthesetermsthatdif-sodfy��2�gtferfromthoseusedinphysics.���1��(9.80m/s2)(0.457s)2Answerswillvary.Someexamples2include,thecompanyConsumers’�1.02mPowerchangeditsnametoConsumers’Energywithoutchanging103.PeoplesometimessaythattheMoonstaysitsproduct,naturalgas.“It’snotjustinitsorbitbecausethe“centrifugalforceenergy,it’spower!”hasappearedinjustbalancesthecentripetalforce,givingthepopularpress.nonetforce.”Explainwhythisideaiswrong.(Chapter8)CumulativeReviewThereisonlyoneforceonthemoon,page282thegravitationalforceofEarth’smass101.Youarehelpingyourgrandmotherwithonit.Thisnetforcegivesitanacceler-somegardeningandhavefilledagarbageationwhichisitscentripetalaccelera-canwithweedsandsoil.NowyouhavetotiontowardEarth’scenter.movethegarbagecanacrosstheyardandrealizeitissoheavythatyouwillneedtopushit,ratherthanliftit.IfthecanhasaChallengeProblemmassof24kg,thecoefficientofkineticfrictionbetweenthecan’sbottomandthepage268muddygrassis0.27,andthestaticcoeffi-Anelectricpumppullswateratarateof0.25cientoffrictionbetweenthosesamesur-m3/sfromawellthatis25mdeep.Thewaterfacesis0.35,howharddoyouhavetoleavesthepumpataspeedof8.5m/s.pushhorizontallytogetthecantojustCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.startmoving?(Chapter5)8.5m/sFyouoncan�Ffriction��sFN��smg�(0.35)(24kg)(9.80m/s2)�82N102.BaseballIfamajorleaguepitcherthrowsafastballhorizontallyataspeedof40.3m/s(90mph)andittravels18.4m(60ft,6in),25mhowfarhasitdroppedbythetimeitcrosseshomeplate?(Chapter6)dfx�dix�vxtd�dfxixsot���vx18.4m�0.0m����0.457s40.3m/s244SolutionsManualPhysics:PrinciplesandProblems
248Chapter10continued1.Whatpowerisneededtoliftthewatertothesurface?TheworkdoneinliftingisFgd�mgd.Therefore,thepowerisWFgdmgdP��������lift�ttt(0.25m3)(1.00�103kg/m3)(9.80m/s2)(25m)�������1.0s�6.1�104W�61kW2.Whatpowerisneededtoincreasethepump’skineticenergy?12.Theworkdoneinincreasingthepump’skineticenergyis��mv212��mvW�KE2mv2Therefore,P����������ttt2t(0.25m3)(1.00�103kg/m3)(8.5m/s)2������(2)(1.0s)�9.0�103W�9.0kW3.Ifthepump’sefficiencyis80percent,howmuchpowermustbedeliveredtothepump?W��oWtPo�oe����100��100����100so,WWiPi��itPo9.0�103WP���100����100i�e80�1.1�104W�11kWCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual245
249
250CHAPTER11EnergyandItsConservationThefinalkineticenergyisPracticeProblemsKE�12��1(875.0kg)(44.0m/s)211.1TheManyFormsofEnergyf�2mv2pages285–292�8.47�105Jpage287Theworkdoneis1.Askaterwithamassof52.0kgmovingatKE5J�2.12�105J2.5m/sglidestoastopoveradistanceoff�KEi�8.47�1024.0m.Howmuchworkdidthefrictionof�6.35�105Jtheicedotobringtheskatertoastop?Howmuchworkwouldtheskaterhaveto3.Acometwithamassof7.85�1011kgdotospeedupto2.5m/sagain?strikesEarthataspeedof25.0km/s.Findthekineticenergyofthecometinjoules,Tobringtheskatertoastop:andcomparetheworkthatisdonebyEarthW�KEf�KEiinstoppingthecomettothe4.2�1015Jof��1mv2��1mv2energythatwasreleasedbythelargest2f2inuclearweaponeverbuilt.��1(52.0kg)(0.00m/s)2�12KE��mv22�1(52.0kg)(2.5m/s)2��1(7.85�1011kg)(2.50�104m/s)222��160J�2.45�1020JTospeedupagain:KEcomet2.45�1020J4������5.8�10Thisisthereverseofthefirstquestion.KEbomb4.2�1015JW�KEf�KEi5.8�104bombswouldberequiredtoproducethesameamountofenergy��1mv2��1mv22f2iusedbyEarthinstoppingthecomet.12���(52.0kg)(2.5m/s)2page291�1(52.0kg)(0.00m/s)24.InExampleProblem1,whatisthepoten-2tialenergyofthebowlingballrelativeto��160Jtherackwhenitisonthefloor?PE�mgh2.An875.0-kgcompactcarspeedsupfrom22.0m/sto44.0m/swhilepassinganother�(7.30kg)(9.80m/s2)(�0.610m)car.Whatareitsinitialandfinalenergies,��43.6Jandhowmuchworkisdoneonthecarto5.Ifyouslowlylowera20.0-kgbagofsandincreaseitsspeed?1.20mfromthetrunkofacartothedrive-TheinitialkineticenergyofthecarisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.way,howmuchworkdoyoudo?KE�12��1(875.0kg)(22.0m/s)2i�2mv2W�Fd�2.12�105J�mg(hf�hi)�(20.0kg)(9.80m/s2)(0.00m�1.20m)��2.35�102JPhysics:PrinciplesandProblemsSolutionsManual247
251Chapter11continued6.Aboyliftsa2.2-kgbookfromhisdesk,SectionReviewwhichis0.80mhigh,toabookshelfthatis2.10mhigh.Whatisthepotentialenergyof11.1TheManyFormsofEnergythebookrelativetothedesk?pages285–292PE�mg(hf�hi)page292�(2.2kg)(9.80m/s2)(2.10m�0.80m)9.ElasticPotentialEnergyYougetaspring-�28Jloadedtoypistolreadytofirebycompress-ingthespring.Theelasticpotentialenergy7.Ifa1.8-kgbrickfallstothegroundfromaofthespringpushestherubberdartoutofchimneythatis6.7mhigh,whatisthethepistol.Youusethetoypistoltoshootchangeinitspotentialenergy?thedartstraightup.DrawbargraphsthatdescribetheformsofenergypresentintheChoosethegroundasthereferencefollowinginstances.level.a.Thedartispushedintothegunbarrel,�PE�mg(hf�hi)therebycompressingthespring.�(1.8kg)(9.80m/s2)(0.0m�6.7m)��1.2�102J8.Awarehouseworkerpicksupa10.1-kgboxfromthefloorandsetsitonalong,SpringDartDart1.1-m-hightable.Heslidesthebox5.0melasticgravitationalkineticalongthetableandthenlowersitbacktopotentialpotentialenergythefloor.Whatwerethechangesintheenergyenergyenergyofthebox,andhowdidthetotalThereshouldbethreebars:oneforenergyoftheboxchange?(Ignorefriction.)thespring’spotentialenergy,oneforTolifttheboxtothetable:gravitationalpotentialenergy,andW�Fdoneforkineticenergy.Thespring’spotentialenergyisatthemaximumCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�mg(hf�hi)level,andtheothertwoarezero.��PEb.Thespringexpandsandthedartleaves�(10.1kg)(9.80m/s2)(1.1m�0.0m)thegunbarrelafterthetriggerispulled.�1.1�102JToslidetheboxacrossthetable,W�0.0becausetheheightdidnotchangeandweignoredfriction.SpringDartDartTolowertheboxtothefloor:elasticgravitationalkineticpotentialpotentialenergyW�Fdenergyenergy�mg(hf�hi)Thekineticenergyisatthemaxi-��PEmumlevel,andtheothertwoare�(10.1kg)(9.80m/s2)(0.0m�1.1m)zero.��1.1�102JThesumofthethreeenergychangesis1.1�102J�0.0J�(�1.1�102J)�0.0J248SolutionsManualPhysics:PrinciplesandProblems
252Chapter11continuedc.Thedartreachesthetopofitsflight.Thebowlingballhaszerokineticenergywhenitisrestingontherackorwhenitisheldnearyourshoulder.Therefore,thetotalworkdoneontheballbyyouandbygravitymustequalzero.SpringDartDartelasticgravitationalkinetic13.PotentialEnergyA90.0-kgrockclimberpotentialpotentialenergyfirstclimbs45.0muptothetopofaquarry,energyenergythendescends85.0mfromthetoptotheThegravitationalpotentialenergyisbottomofthequarry.Iftheinitialheightisatthemaximumlevel,andtheotherthereferencelevel,findthepotentialenergytwoarezero.ofthesystem(theclimberandEarth)atthetopandatthebottom.Drawbargraphsfor10.PotentialEnergyA25.0-kgshellisshotbothsituations.fromacannonatEarth’ssurface.Therefer-3.97�104JencelevelisEarth’ssurface.WhatisthegravitationalpotentialenergyofthesystemAtthebottomwhentheshellisat425m?WhatisthechangeinpotentialenergywhentheshellAtthefallstoaheightof225m?topa.PE�mgh�3.53�104J�(25.0kg)(9.80m/s2)(425m)PE�mgh�1.04�105JAtthetop,b.PE�mghPE�(90.0kg)(9.80m/s2)(�45.0m)�(25.0kg)(9.80m/s2)(225m)�3.97�104J�5.51�104JAtthebottom,ThechangeinenergyisPE�(90.0kg)(9.80m/s2)(�45.0m�85.0m)(1.04�105J)�(5.51�104J)�4.89�104J��3.53�104J11.RotationalKineticEnergySupposesome14.CriticalThinkingKarlusesanairhosetochildrenpushamerry-go-roundsothatitexertaconstanthorizontalforceonapuck,turnstwiceasfastasitdidbeforetheypushedwhichisonafrictionlessairtable.Hekeepsit.Whataretherelativechangesinangularthehoseaimedatthepuck,therebycreatingmomentumandrotationalkineticenergy?aconstantforceasthepuckmovesafixeddistance.Theangularmomentumisdoubledbecauseitisproportionaltotheangulara.Explainwhathappensintermsofworkvelocity.Therotationalkineticenergyisandenergy.Drawbargraphs.quadrupledbecauseitisproportionaltothesquareoftheangularvelocity.KEinitial��WKEfinalThechildrendidworkinrotatingtheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.merry-go-round.KarlexertedaconstantforceFoveradistancedanddidanamountof12.Work-EnergyTheoremHowcanyouworkW�Fdonthepuck.Thisworkapplythework-energytheoremtoliftingachangedthekineticenergyofthebowlingballfromastorageracktoyourpuck.shoulder?Physics:PrinciplesandProblemsSolutionsManual249
253Chapter11continuedW�(KEThesystemisthebike�rider�Earth.f�KEi)Therearenoexternalforces,sototal��1mv2��1mv22f2ienergyisconserved.12KE��1mv2��2mvf2b.SupposeKarlusesadifferentpuckwith��1(85.0kg)(8.5m/s)22halfthemassofthefirstone.Allotherconditionsremainthesame.Howwill�3.1�103JthekineticenergyandworkdifferfromKEi�PEi�KEf�PEfthoseinthefirstsituation?�1mv2�0�0�mghIfthepuckhashalfthemass,itstill2receivesthesameamountofworkv2(8.5m/s)2andhasthesamechangeinkinetich�����2g(2)(9.80m/s2)energy.However,thesmallermass�3.7mwillmovefasterbyafactorof1.414.c.Explainwhathappenedinpartsaandb16.Supposethatthebikeriderinproblem15intermsofimpulseandmomentum.pedaledupthehillandnevercametoaThetwopucksdonothavethesamestop.Inwhatsystemisenergyconserved?finalmomentum.FromwhatformofenergydidthebikegainMomentumofthefirstpuck:mechanicalenergy?pThesystemofEarth,bike,andrider1�m1v1remainsthesame,butnowtheenergyMomentumofthesecondpuck:involvedisnotmechanicalenergyp2�m2v2alone.Theridermustbeconsideredas1havingstoredenergy,someofwhichis����m21�(1.414v1)convertedtomechanicalenergy.�0.707p1Energycamefromthechemicalpoten-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tialenergystoredintherider’sbody.Thus,thesecondpuckhaslessmomentumthanthefirstpuckdoes.17.AskierstartsfromrestatthetopofaBecausethechangeinmomentum45.0-m-highhill,skisdowna30°inclineisequaltotheimpulseprovidedbyintoavalley,andcontinuesupa40.0-m-theairhose,thesecondpuckhighhill.Theheightsofbothhillsaremea-receivesasmallerimpulse.suredfromthevalleyfloor.Assumethatyoucanneglectfrictionandtheeffectoftheskipoles.HowfastistheskiermovingatPracticeProblemsthebottomofthevalley?Whatistheskier’s11.2ConservationofEnergyspeedatthetopofthenexthill?Dotheanglesofthehillsaffectyouranswers?pages293–301Bottomofvalley:page297KE15.Abikeriderapproachesahillataspeedofi�PEi�KEf�PEf8.5m/s.Thecombinedmassofthebike12�00�mgh��mvandtherideris85.0kg.Chooseasuitable2system.Findtheinitialkineticenergyofthev2�2ghsystem.Theridercoastsupthehill.Assumingthereisnofriction,atwhatv��2�ghheightwillthebikecometorest?2)(45.0��(2)(9.8��0m/s��m)250SolutionsManualPhysics:PrinciplesandProblems
254Chapter11continued�29.7m/sConservationofmomentum:Topofnexthill:mv�(m�M)V,orKEi�PEi�KEf�PEf��(m�M)Vv�m0�mgh�12�mghi�2mvf(0.00800kg�9.00kg)(0.100m/s)�����0.00800kgv2�2g(hi�hf)�1.13�102m/s��2�g(hi�hf)20.A0.73-kgmagnetictargetissuspendedona��(2)(9.8�0m��s�2)(45.0�m�40.0m�)�string.A0.025-kgmagneticdart,shothori-�9.90m/szontally,strikesthetargethead-on.ThedartNo,theanglesdonothaveanyimpact.andthetargettogether,actinglikeapendu-lum,swing12.0cmabovetheinitiallevel18.Inabelly-flopdivingcontest,thewinnerisbeforeinstantaneouslycomingtorest.thediverwhomakesthebiggestsplashupona.Sketchthesituationandchooseasystem.hittingthewater.Thesizeofthesplashdependsnotonlyonthediver’sstyle,butSystemalsoontheamountofkineticenergythatthediverhas.Consideracontestinwhicheachdiverjumpsfroma3.00-mplatform.Onediverhasamassof136kgandsimplystepsofftheplatform.Anotherdiverhasamassof102kgandleapsupwardfromtheplatform.12cmHowhighwouldtheseconddiverhavetoPE�0leaptomakeacompetitivesplash?ThesystemincludesthesuspendedUsingthewaterasareferencelevel,thetargetandthedart.kineticenergyonentryisequaltotheb.Decidewhatisconservedineachpartpotentialenergyofthediveratthetopandexplainyourdecision.ofhisflight.ThelargediverhasPE�mgh�(136kg)(9.80m/s2)(3.00m)�Onlymomentumisconservedinthe3Jinelasticdart-targetcollision,so4.00�10mvToequalthis,thesmallerdiverwouldi�MVi�(m�M)VfhavetojumptowhereVi�0sincethetargetisini-tiallyatrestandV4.00�103Jfisthecommonh�����4.00mvelocityjustafterimpact.Asthe(102kg)(9.80m/s2)dart-targetcombinationswingsThus,thesmallerdiverwouldhavetoupward,energyisconserved,soleap1.00mabovetheplatform.�PE��KEor,atthetopoftheswing,(m�M)gh�12f�2(m�M)(Vf)page30019.An8.00-gbulletisfiredhorizontallyintoa9.00-kgblockofwoodonanairtableandisembeddedinit.Afterthecollision,theCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.blockandbulletslidealongthefrictionlesssurfacetogetherwithaspeedof10.0cm/s.Whatwastheinitialspeedofthebullet?Physics:PrinciplesandProblemsSolutionsManual251
255Chapter11continuedc.Whatwastheinitialvelocityofthedart?SolveforVf.Vf���2ghfSubstitutevfintothemomentumequationandsolveforvi.m�Mvi���m���2�ghf0.025kg�0.73kg2)(0.12��������(2)(9.8�0m/s��0m)��0.025kg�46m/s21.A91.0-kghockeyplayerisskatingoniceat5.50m/s.Anotherhockeyplayerofequalmass,movingat8.1m/sinthesamedirection,hitshimfrombehind.Theyslideofftogether.a.Whatarethetotalenergyandmomentuminthesystembeforethecollision?KE�12��1m2i�2m1v122v2��1(91.0kg)(5.50m/s)2��1(91.0kg)(8.1m/s)222�4.4�103Jpi�m1v1�m2v2�(91.0kg)(5.5m/s)�(91.0kg)(8.1m/s)�1.2�103kgm/sb.Whatisthevelocityofthetwohockeyplayersafterthecollision?Afterthecollision:Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pi�pfm1v1�m2v2�(m1�m2)vfm1v1�m2v2v��f�m1�m2(91.0kg)(5.50m�s)�(91.0kg)(8.1m�s)������91.0kg�91.0kg�6.8m/sc.Howmuchenergywaslostinthecollision?Thefinalkineticenergyis12KE�f�2(mi�mf)vf12��(91.0kg�91.0kg)(6.8m/s)2�4.2�103JThus,theenergylostinthecollisionisKE3J�4.2�103Ji�KEf�4.4�10�2�102J252SolutionsManualPhysics:PrinciplesandProblems
256Chapter11continued25.KineticEnergyIntabletennis,averylightSectionReviewbuthardballishitwithahardrubberor11.2ConservationofEnergywoodenpaddle.Intennis,amuchsofterpages293–301ballishitwitharacket.Whyarethetwosetsofequipmentdesignedinthisway?page301Canyouthinkofotherball-paddlepairsin22.ClosedSystemsIsEarthaclosed,isolatedsports?Howaretheydesigned?system?Supportyouranswer.TheballsandthepaddleandracketareTosimplifyproblemsthattakeplacedesignedtomatchsothatthemaximumoverashorttime,Earthisconsideredaamountofkineticenergyispassedfromclosedsystem.Itisnotactuallyisolated,thepaddleorrackettotheball.Asofterhowever,becauseitisacteduponbytheballreceivesenergywithlesslossfromagravitationalforcesfromtheplanets,thesofterpaddleorracket.Othercombina-Sun,andotherstars.Inaddition,Earthistionsareagolfballandclub(bothhard)therecipientofcontinuouselectromag-andabaseballandbat(alsobothhard).neticenergy,primarilyfromtheSun.26.PotentialEnergyArubberballisdropped23.EnergyAchildjumpsonatrampoline.fromaheightof8.0montoahardconcreteDrawbargraphstoshowtheformsoffloor.Ithitsthefloorandbouncesrepeat-energypresentinthefollowingsituations.1edly.Eachtimeithitsthefloor,itloses��a.Thechildisatthehighestpoint.5ofitstotalenergy.Howmanytimeswillitbouncebeforeitbouncesbackuptoaheightofonlyabout4m?Etotal�mghTrampolineChildChildelasticgravitationalkineticSincethereboundheightisproportionalpotentialpotentialenergytoenergy,eachbouncewillreboundtoenergyenergy4�theheightofthepreviousbounce.5b.Thechildisatthelowestpoint.4Afteronebounce:h����(8m)�6.4m54Aftertwobounces:h����(6.4m)�55.12mTrampolineChildChild4elasticgravitationalkineticAfterthreebounces:h����5(5.12m)�potentialpotentialenergy4.1menergyenergy24.KineticEnergySupposeaglobofchew-inggumandasmall,rubberballcollidehead-oninmidairandthenreboundapart.Wouldyouexpectkineticenergytobecon-served?Ifnot,whathappenstotheenergy?EventhoughtherubberballreboundsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.withlittleenergyloss,kineticenergywouldnotbeconservedinthiscasebecausetheglobofchewinggumprob-ablywasdeformedinthecollision.Physics:PrinciplesandProblemsSolutionsManual253
257Chapter11continued27.EnergyAsshowninFigure11-15,aChapterAssessment36.0-kgchildslidesdownaplaygroundslidethatis2.5mhigh.AtthebottomoftheConceptMappingslide,sheismovingat3.0m/s.Howmuchpage306energywaslostasshesliddowntheslide?29.Completetheconceptmapusingthefol-lowingterms:gravitationalpotentialenergy,elasticpotentialenergy,kineticenergy.36.0kgEnergykineticpotential2.5mlinearrotationalgravitationalelasticMasteringConcepts■Figure11-15page306EUnlessotherwisedirected,assumethatairresis-i�mghtanceisnegligible.�(36.0kg)(9.80m/s2)(2.5m)30.Explainhowworkandachangeinenergy�880Jarerelated.(11.1)12Ef��2mvTheworkdoneonanobjectcausesachangeintheobject’senergy.Thisis12��(36.0kg)(3.0m/s)thework-energytheorem.2�160J31.Whatformofenergydoesawound-upCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Energyloss�880J–160Jwatchspringhave?Whatformofenergy�720Jdoesafunctioningmechanicalwatchhave?Whenawatchrunsdown,whathashap-28.CriticalThinkingAballdrops20m.penedtotheenergy?(11.1)Whenithasfallenhalfthedistance,orThewound-upwatchspringhaselastic10m,halfofitsenergyispotentialandhalfpotentialenergy.Thefunctioningwatchiskinetic.Whentheballhasfallenforhalfhaselasticpotentialenergyandrota-theamountoftimeittakestofall,willtionalkineticenergy.Thewatchrunsmore,less,orexactlyhalfofitsenergybedownwhenalloftheenergyhasbeenpotentialenergy?convertedtoheatbyfrictionintheTheballfallsmoreslowlyduringthegearsandbearings.beginningpartofitsdrop.Therefore,inthefirsthalfofthetimethatitfalls,it32.Explainhowenergychangeandforcearewillnothavetraveledhalfofthedis-related.(11.1)tancethatitwillfall.Therefore,theballAforceexertedoveradistancedoeswillhavemorepotentialenergythanwork,whichproducesachangeinenergy.kineticenergy.33.Aballisdroppedfromthetopofabuild-ing.Youchoosethetopofthebuildingtobethereferencelevel,whileyourfriendchoosesthebottom.Explainwhetherthe254SolutionsManualPhysics:PrinciplesandProblems
258Chapter11continuedenergycalculatedusingthesetworeference38.Thesportofpole-vaultingwasdrasticallylevelsisthesameordifferentforthefol-changedwhenthestiff,woodenpoleswerelowingsituations.(11.1)replacedbyflexible,fiberglasspoles.a.theball’spotentialenergyatanypointExplainwhy.(11.2)ThepotentialenergiesaredifferentAflexible,fiberglasspolecanstoreelas-duetothedifferentreferencelevels.ticpotentialenergybecauseitcanbebenteasily.Thisenergycanbereleasedb.thechangeintheball’spotentialenergytopushthepole-vaulterhighervertically.asaresultofthefallBycontrast,thewoodenpoledoesnotThechangesinthepotentialener-storeelasticpotentialenergy,andthegiesasaresultofthefallareequalpole-vaulter’smaximumheightislimitedbecausethechangeinhisthesamebythedirectconversionofkineticenergyforbothreferencelevels.togravitationalpotentialenergy.c.thekineticenergyoftheballatanypointThekineticenergiesoftheballat39.Youthrowaclayballatahockeypuckonanypointareequalbecausetheice.Thesmashedclayballandthehockeyvelocitiesarethesame.pucksticktogetherandmoveslowly.(11.2)a.Ismomentumconservedinthecollision?34.CanthekineticenergyofabaseballeverbeExplain.negative?(11.1)ThetotalmomentumoftheballandThekineticenergyofabaseballcanthepucktogetherisconservedinneverbenegativebecausethekineticthecollisionbecausetherearenoenergydependsonthesquareoftheunbalancedforcesonthissystem.velocity,whichisalwayspositive.b.Iskineticenergyconserved?Explain.35.CanthegravitationalpotentialenergyofaThetotalkineticenergyisnotbaseballeverbenegative?Explainwithoutconserved.Partofitislostintheusingaformula.(11.1)smashingoftheclayballandtheadhesionoftheballtothepuck.Thegravitationalpotentialenergyofabaseballcanbenegativeiftheheightof40.Drawenergybargraphsforthefollowingtheballislowerthanthereferencelevel.processes.(11.2)36.Ifasprinter’svelocityincreasestothreea.Anicecube,initiallyatrest,slidesdowntimestheoriginalvelocity,bywhatfactorafrictionlessslope.doesthekineticenergyincrease?(11.1)Thesprinter’skineticenergyincreasesbyafactorof9,becausethevelocityissquared.PEiKEiPEfKEf37.Whatenergytransformationstakeplaceb.Anicecube,initiallymoving,slidesupawhenanathleteispole-vaulting?(11.2)frictionlessslopeandinstantaneouslyThepole-vaulterruns(kineticenergy)comestorest.andbendsthepole,therebyaddingelasticpotentialenergytothepole.AsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.he/sheliftshis/herbody,thatkineticandelasticpotentialenergyistrans-ferredintokineticandgravitationalPEiKEiPEfKEfpotentialenergy.Whenhe/shereleasesthepole,allofhis/herenergyiskineticandgravitationalpotentialenergy.Physics:PrinciplesandProblemsSolutionsManual255
259Chapter11continued41.Describethetransformationsfromkinetic44.Acompactcarandatrailertruckarebothenergytopotentialenergyandviceversafortravelingatthesamevelocity.Didthecararoller-coasterride.(11.2)engineorthetruckenginedomoreworkinOnaroller-coasterride,thecarhasacceleratingitsvehicle?mostlypotentialenergyatthetopsofThetrailertruckhasmorekineticenergy,thehillsandmostlykineticenergyat12,becauseithasgreatermassKE��mvthebottomsofthehills.2thanthecompactcar.Thus,according42.Describehowthekineticenergyandelastictothework-energytheorem,thetruck’spotentialenergyarelostinabouncingenginemusthavedonemorework.rubberball.Describewhathappenstothemotionoftheball.(11.2)45.CatapultsMedievalwarriorsusedcatapultstoassaultcastles.SomecatapultsworkedOneachbounce,some,butnotall,ofthebyusingatightlywoundropetoturntheball’skineticenergyisstoredaselasticcatapultarm.Whatformsofenergyarepotentialenergy;theball’sdeformationinvolvedincatapultingarocktothecastledissipatestherestoftheenergyasther-wall?malenergyandsound.Afterthebounce,thestoredelasticpotentialenergyisElasticpotentialenergyisstoredinthereleasedaskineticenergy.Duetothewoundrope,whichdoesworkontheenergylossesinthedeformation,eachrock.Therockhaskineticandpotentialsubsequentbouncebeginswithasmallerenergyasitfliesthroughtheair.Whenamountofkineticenergy,andresultsinithitsthewall,theinelasticcollisiontheballreachingalowerheight.causesmostofthemechanicalenergyEventually,alloftheball’senergyisdissi-tobeconvertedtothermalandsoundpated,andtheballcomestorest.energyandtodoworkbreakingapartthewallstructure.Someofthemechan-ApplyingConceptsicalenergyappearsinthefragmentsthrownfromthecollision.pages306–307Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.43.Thedriverofaspeedingcarappliesthe46.Twocarscollideandcometoacompletebrakesandthecarcomestoastop.Thestop.Wheredidalloftheirenergygo?systemincludesthecarbutnottheroad.TheenergywentintobendingsheetApplythework-energytheoremtothefol-metalonthecars.Energyalsowaslostlowingsituations.duetofrictionalforcesbetweenthea.Thecar’swheelsdonotskid.carsandthetires,andintheformofIfthecarwheelsdonotskid,thethermalenergyandsound.brakesurfacesrubagainsteachotheranddoworkthatstopsthecar.47.Duringaprocess,positiveworkisdoneonaTheworkthatthebrakesdoisequalsystem,andthepotentialenergydecreases.tothechangeinkineticenergyofCanyoudetermineanythingaboutthechangethecar.Thebrakesurfacesheatupinkineticenergyofthesystem?Explain.becausethekineticenergyistrans-Theworkequalsthechangeinthetotalformedtothermalenergy.mechanicalenergy,W��(KE�PE).IfWb.Thebrakeslockandthecar’swheelsskid.ispositiveand�PEisnegative,then�KEIfthebrakeslockandthecarwheelsmustbepositiveandgreaterthanW.skid,thewheelsrubbingontheroadaredoingtheworkthatstopsthecar.48.Duringaprocess,positiveworkisdoneonaThetiresurfacesheatup,notthesystem,andthepotentialenergyincreases.Canbrakes.Thisisnotanefficientwaytoyoutellwhetherthekineticenergyincreased,stopacar,anditruinsthetires.decreased,orremainedthesame?Explain.256SolutionsManualPhysics:PrinciplesandProblems
260Chapter11continuedTheworkequalsthechangeinthetotal51.Givespecificexamplesthatillustratethemechanicalenergy,W��(KE�PE).Iffollowingprocesses.Wispositiveand�PEispositive,thena.Workisdoneonasystem,therebyyoucannotsayanythingconclusiveincreasingkineticenergywithnoabout�KE.changeinpotentialenergy.pushingahockeypuckhorizontally49.SkatingTwoskatersofunequalmasshaveacrossice;systemconsistsofthesamespeedandaremovinginthesamehockeypuckonlydirection.Iftheiceexertsthesamefrictionalforceoneachskater,howwillthestoppingb.Potentialenergyischangedtokineticdistancesoftheirbodiescompare?energywithnoworkdoneonthesystem.Thelargerskaterwillhavemorekineticdroppingaball;systemconsistsofenergy.ThekineticenergyofeachballandEarthskaterwillbedissipatedbythenegativec.Workisdoneonasystem,increasingwork,W�Fd,donebythefrictionofpotentialenergywithnochangeintheice.Sincethefrictionalforcesarekineticenergy.equal,thelargerskaterwillgofarthercompressingthespringinatoypis-beforestopping.tol;systemconsistsofspringonlyd.Kineticenergyisreduced,butpotential50.Youswinga55-gmassontheendofaenergyisunchanged.Workisdoneby0.75-mstringaroundyourheadinanearlythesystem.horizontalcircleatconstantspeed,asshowninFigure11-16.Acar,speedingonaleveltrack,brakesandreducesitsspeed.52.RollerCoasterYouhavebeenhiredtomakearollercoastermoreexciting.Theownerswantthespeedatthebottomofthe0.75mfirsthilldoubled.Howmuchhighermust55gthefirsthillbebuilt?Thehillmustbemadehigherbyafactorof4.53.Twoidenticalballsarethrownfromthetop■Figure11-16ofacliff,eachwiththesamespeed.Oneisa.Howmuchworkisdoneonthemassthrownstraightup,theotherstraightdown.bythetensionofthestringinoneHowdothekineticenergiesandspeedsofrevolution?theballscompareastheystriketheground?NoworkisdonebythetensionforceEventhoughtheballsaremovinginonthemassbecausethetensionisoppositedirections,theyhavethesamepullingperpendiculartothemotionkineticenergyandpotentialenergyofthemass.whentheyarethrown.Therefore,theyb.Isyouranswertopartainagreementwillhavethesamemechanicalenergywiththework-energytheorem?Explain.andspeedwhentheyhittheground.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thisdoesnotviolatethework-energytheorembecausethekineticenergyofthemassisconstant;itismovingataconstantspeed.Physics:PrinciplesandProblemsSolutionsManual257
261Chapter11continuedMasteringProblemsc.Whatistheratioofthekineticenergiesinpartsaandb?Explain.Unlessotherwisedirected,assumethatairresistanceisnegligible.�1�(mv2)21v2(10.0)241������11.1TheManyFormsofEnergy12)v2(5.0)21��(mv222pages307–308Level1Twicethevelocitygivesfourtimes54.A1600-kgcartravelsataspeedof12.5m/s.thekineticenergy.ThekineticenergyWhatisitskineticenergy?isproportionaltothesquareofthevelocity.KE��1mv2��1(1600kg)(12.5m/s)22258.KatiaandAngelaeachhaveamassof45kg,�1.3�105Jandtheyaremovingtogetherwithaspeedof10.0m/s.55.Aracingcarhasamassof1525kg.Whatisa.Whatistheircombinedkineticenergy?itskineticenergyifithasaspeedof108km/h?KE�12��1(m2c�2mv2K�mA)v12KE��mv12��(45kg�45kg)(10.0m/s)221(108km�h)(1000m�km)2��2(1525kg)�����3600s�h�4.5�103J�6.86�105Jb.WhatistheratiooftheircombinedmasstoKatia’smass?56.ShawnandhisbikehaveacombinedmassmK�mA45kg�45kg�����of45.0kg.Shawnrideshisbike1.80kminmK45kg10.0minataconstantvelocity.Whatis2���Shawn’skineticenergy?112�1md2c.WhatistheratiooftheircombinedKE��mv����22tkineticenergytoKatia’skineticenergy?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2Explain.1(1.80km)(1000m�km)��(45kg)�����2(10.0min)(60s�min)KE�12��1(45kg)(10.0m/s)2K�2mKv2�203J�2.3�103J57.Tonyhasamassof45kgandismoving12��(mwithaspeedof10.0m/s.KEC2K�mA)vmK�mA�������a.FindTony’skineticenergy.KEK�1�m2mK2KvKE��1mv2��1(45kg)(10.0m/s)2222��1�2.3�103JTheratiooftheircombinedkineticb.Tony’sspeedchangesto5.0m/s.NowenergytoKatia’skineticenergyiswhatishiskineticenergy?thesameastheratiooftheircom-KE��1mv2��1(45kg)(5.0m/s)2binedmasstoKatia’smass.Kinetic22energyisproportionaltomass.�5.6�102J258SolutionsManualPhysics:PrinciplesandProblems
262Chapter11continued59.TrainInthe1950s,anexperimentaltrain,Fg4kg,wasNowm���whichhadamassof2.50�10gpoweredacrossaleveltrackbyajetengine12thatproducedathrustof5.00�105Nfora��mv2Sod�distanceof509m.Fa.Findtheworkdoneonthetrain.1Fg2�2���g��vW�Fd�(5.00�105N)(509m)���F�2.55�108J114,700N2�2����2�(25.0m/s)b.Findthechangeinkineticenergy.��9.80�m/s�7100N�KE�W�2.55�108J�66mc.Findthefinalkineticenergyofthetrainifitstartedfromrest.61.A15.0-kgcartismovingwithavelocityof�KE�KEf�KEi7.50m/sdownalevelhallway.Aconstantforceof10.0Nactsonthecart,anditssoKEf��KE�KEivelocitybecomes3.20m/s.�2.55�108J�0.00Ja.Whatisthechangeinkineticenergyof�2.55�108Jthecart?�KE�KE�12�v2)d.Findthefinalspeedofthetrainiftheref�KEi�2m(vfihadbeennofriction.12���(15.0kg)((3.20m/s)122KE�f�2mvf(7.50m/s)2)KESov2�f��345Jf1��m2b.Howmuchworkwasdoneonthecart?2.55�108JW��KE��345J����1�(2.50�104kg)c.Howfardidthecartmovewhilethe2forceacted?Sovf��2.04���104m2�/s2�143m/sW�FdW�345J60.CarBrakesA14,700-Ncaristravelingatsod������34.5mF�10.0N25m/s.Thebrakesareappliedsuddenly,andthecarslidestoastop,asshownin62.HowmuchpotentialenergydoesDeAnnaFigure11-17.Theaveragebrakingforcewithamassof60.0kg,gainwhenshebetweenthetiresandtheroadis7100N.climbsagymnasiumropeadistanceofHowfarwillthecarslideoncethebrakes3.5m?areapplied?PE�mghBeforeAfter�(60.0kg)(9.80m/s2)(3.5m)(initial)(final)�2.1�103Jv�25m/sv�0.0m/s63.BowlingA6.4-kgbowlingballisliftedCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2.1mintoastoragerack.Calculatetheincreaseintheball’spotentialenergy.m�14,700NPE�mgh■Figure11-17�(6.4kg)(9.80m/s2)(2.1m)12W�Fd��mv�1.3�102J2Physics:PrinciplesandProblemsSolutionsManual259
263Chapter11continued64.Maryweighs505N.ShewalksdownaLevel2flightofstairstoalevel5.50mbelowher69.TennisItisnotuncommonduringtheservestartingpoint.WhatisthechangeinMary’sofaprofessionaltennisplayerfortheracketpotentialenergy?toexertanaverageforceof150.0NonthePE�mg�h�Fball.Iftheballhasamassof0.060kgandisg�hincontactwiththestringsoftheracket,as�(505N)(�5.50m)showninFigure11-18,for0.030s,whatis��2.78�103Jthekineticenergyoftheballasitleavestheracket?Assumethattheballstartsfromrest.65.WeightliftingAweightlifterraisesa180-kgbarbelltoaheightof1.95m.Whatistheincreaseinthepotentialenergyofthebarbell?PE�mgh�(180kg)(9.80m/s2)(1.95m)150.0N�3.4�103J66.A10.0-kgtestrocketisfiredverticallyfromCapeCanaveral.Itsfuelgivesitakinetic■Figure11-18energyof1960JbythetimetherocketFt�m�v�mvf�mviandvi�0engineburnsallofthefuel.Whatadditionalheightwilltherocketrise?Ft(150.0N)(3.0�10�2s)sov����f��m6.0�10�2kgPE�mgh�KE�75m/sKE1960h������mg(10.0kg)(9.80m/s2)12KE��mv2�20.0m��1(6.0�10�2kg)(75m/s)2267.Antwanraiseda12.0-NphysicsbookfromCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.atable75cmabovethefloortoashelf�1.7�102J2.15mabovethefloor.Whatwasthechangeinthepotentialenergyofthe70.Pam,wearingarocketpack,standsonfric-system?tionlessice.Shehasamassof45kg.Therocketsuppliesaconstantforcefor22.0m,PE�mg�h�Fg�h�Fg(hf�hi)andPamacquiresaspeedof62.0m/s.�(12.0N)(2.15m�0.75m)a.Whatisthemagnitudeoftheforce?�17J12�KE�f�2mvf68.Ahallwaydisplayofenergyisconstructedinwhichseveralpeoplepullonaropethat��1(45kg)(62.0m�s)22liftsablock1.00m.Thedisplayindicatesthat1.00Jofworkisdone.Whatisthe�8.6�104Jmassoftheblock?b.WhatisPam’sfinalkineticenergy?W�PE�mghWorkdoneonPamequalsherW1.00Jchangeinkineticenergy.m������gh(9.80m/s2)(1.00m)W�Fd��KE�KEf�KEi�0.102kgKEi�0JKEf8.6�104JSo,F�����d22.0m�3.9�103N260SolutionsManualPhysics:PrinciplesandProblems
264Chapter11continued71.CollisionA2.00�103-kgcarhasaspeedof11.2ConservationofEnergy12.0m/s.Thecarthenhitsatree.Thetreepages308–309doesn’tmove,andthecarcomestorest,asLevel1showninFigure11-19.73.A98.0-Nsackofgrainishoistedtoastor-ageroom50.0mabovethegroundfloorofBeforeagrainelevator.(initial)After(final)a.Howmuchworkwasdone?vi�12.0m/svf�0.0m/sW��PE�mg�h�Fg�h�(98.0N)(50.0m)�4.90�103J3m�2.00�10kgb.Whatistheincreaseinpotentialenergy■Figure11-19ofthesackofgrainatthisheight?a.Findthechangeinkineticenergyof3J�PE�W�4.90�10thecar.1c.Theropebeingusedtoliftthesackof�KE�KE�2�v2)f�KEi�2m(vfigrainbreaksjustasthesackreachesthe��1(2.00�103kg)((0.0m/s)2�storageroom.Whatkineticenergydoes2thesackhavejustbeforeitstrikesthe(12.0m/s)2)groundfloor?��1.44�105JKE��PE�4.90�103Jb.Findtheamountofworkdoneasthefrontofthecarcrashesintothetree.74.A20-kgrockisontheedgeofa100-mcliff,5JasshowninFigure11-20.W��KE��1.44�10c.Findthesizeoftheforcethatpushedin20kgthefrontofthecarby50.0cm.W�FdWsoF��100md�1.44�105J���0.500m��2.88�105N■Figure11-20a.Whatpotentialenergydoestherock72.Aconstantnetforceof410Nisappliedpossessrelativetothebaseofthecliff?upwardtoastonethatweighs32N.ThePE�mgh�(20kg)(9.80m/s2)(100m)upwardforceisappliedthroughadistance4J�2�10of2.0m,andthestoneisthenreleased.Tob.Therockfallsfromthecliff.Whatisitswhatheight,fromthepointofrelease,willkineticenergyjustbeforeitstrikesthethestonerise?ground?W�Fd�(410N)(2.0m)�8.2�102JKE��PE�2�104JButW��PE�mg�h,soc.WhatspeeddoestherockhaveasitW8.2�102J�h������26mstrikestheground?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mg32N12KE��mv22KE(2)(2�104J)v����������m20kg�40m/sPhysics:PrinciplesandProblemsSolutionsManual261
265Chapter11continued75.ArcheryAnarcherputsa0.30-kgarrowto77.Aphysicsbookofunknownmassisthebowstring.Anaverageforceof201Nisdropped4.50m.Whatspeeddoesthebookexertedtodrawthestringback1.3m.havejustbeforeithitstheground?a.AssumingthatalltheenergygoesintoKE�PEthearrow,withwhatspeeddoesthe12�mgh�mvarrowleavethebow?2WorkdoneonthestringincreasesThemassofthebookdividesout,sothestring’selasticpotentialenergy.1�v2�ghW��PE�Fd2Allofthestoredpotentialenergyisv��2�gh��2(9.80��m/s2)(4.50�m)�transformedtothearrow’skinetic�9.39m/senergy.KE��1mv2��PE�Fd78.RailroadCarArailroadcarwithamassof25.0�105kgcollideswithastationaryrail-2�2Fdroadcarofequalmass.Afterthecollision,v�mthetwocarslocktogetherandmoveoffat4.0m/s,asshowninFigure11-21.2Fd(2)(201N)(1.3m)v�����������m0.30kgm�5.0�105kg�42m/sv�4.0m/sb.Ifthearrowisshotstraightup,howhighdoesitrise?Thechangeinthearrow’spotentialenergyequalstheworkdonetopullthestring.■Figure11-21�PE�mg�h�Fda.Beforethecollision,thefirstrailroadcarFd(201N)(1.3m)�h������2)wasmovingat8.0m/s.WhatwasitsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mg(0.30kg)(9.80m�smomentum?�89mmv�(5.0�105kg)(8.0m/s)76.A2.0-kgrockthatisinitiallyatrestloses�4.0�106kgm/s407Jofpotentialenergywhilefallingtob.Whatwasthetotalmomentumofthetheground.Calculatethekineticenergytwocarsafterthecollision?thattherockgainswhilefalling.Whatistherock’sspeedjustbeforeitstrikestheBecausemomentumisconserved,itground?mustbe4.0�106kgm/sPEc.Whatwerethekineticenergiesofthei�KEi�PEf�KEftwocarsbeforeandafterthecollision?KEi�0Beforethecollision:So,KE12f�PEi�PEf�407JKEi��2mvKE�1215kg)(8.0m/s)2f�2mvf��(5.0�1022KEv2��f�1.6�107JfmAfterthecollision:v2KEf��(2)(407J)KE�12f����m���(2.0kg)f�2mv�2.0�101m/s262SolutionsManualPhysics:PrinciplesandProblems
266Chapter11continued��1(5.0�105kg�5.0�105kg)b.IfKellimovesthroughthelowestpoint2at2.0m/s,howmuchworkwasdone(4.0m/s)2ontheswingbyfriction?�8.0�106JTheworkdonebyfrictionequalsthechangeinmechanicalenergy.d.Accountforthelossofkineticenergy.W��PE��KEWhilemomentumwasconservedduringthecollision,kineticenergy�mg(h�12f�hi)�2mvfwasnot.Theamountnotconservedwasturnedintothermalenergyand�(420N)(0.40m�1.00m)�soundenergy.1420N2�2����9.80m�s2(2.0m�s)79.Fromwhatheightwouldacompactcar��1.7�102Jhavetobedroppedtohavethesamekineticenergythatithaswhenbeingdriven81.Hakeemthrowsa10.0-gballstraightdownat1.00�102km/h?fromaheightof2.0m.Theballstrikesthe2km1000m1hfloorataspeedof7.5m/s.Whatwasthev��1.00�10��������h1km3600sinitialspeedoftheball?�27.8m/sKEf�KEi�PEiKE�PE12�1mv2�mgh�mv�12f2i�mv2�mgh2themassoftheballdividesout,so�1v2�ghv2�v2�2gh,2ifv2(27.8m/s)2v��v2�2�ghh�����i�f2g2(9.80m/s2)�39.4m��(7.5m�/s)�2��(2)(9.�80m/s�2)(2.0�m)�4.1m/sLevel280.Kelliweighs420N,andsheissittingona82.SlideLorena’smassis28kg.Sheclimbstheplaygroundswingthathangs0.40mabove4.8-mladderofaslideandreachesavelocitytheground.Hermompullstheswingbackof3.2m/satthebottomoftheslide.Howandreleasesitwhentheseatis1.00mmuchworkwasdonebyfrictiononLorena?abovetheground.TheworkdonebyfrictiononLorenaa.HowfastisKellimovingwhentheswingequalsthechangeinhermechanicalpassesthroughitslowestposition?energy.�PE�mg�h�mg(hf�hi)W��PE��KE�KE��1m(v2�v2)��1mv2�mg(h�12�v2)2fi2ff�hi)�2m(vfiByconservationofmechanicalenergy:�(28kg)(9.80m�s2)(0.0m�4.8m)��PE��KE�0�1(28kg)((3.2m�s)2�(0.0m�s)2)2mg(h�12�0f�hi)�2mvf3JCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��1.2�10vf���2g(hi�hf)83.Apersonweighing635Nclimbsupa��(2)(9.8��0m�s2�)(1.00�m�0�.40m)�laddertoaheightof5.0m.UsethepersonandEarthasthesystem.�3.4m/sPhysics:PrinciplesandProblemsSolutionsManual263
267Chapter11continueda.Drawenergybargraphsofthesystem86.HighJumpTheworldrecordforthemen’sbeforethepersonstartstoclimbthehighjumpisabout2.45m.Toreachthatladderandafterthepersonstopsattheheight,whatistheminimumamountoftop.Hasthemechanicalenergyworkthata73.0-kgjumpermustexertinchanged?Ifso,byhowmuch?pushingofftheground?W��E�mgh3200J2)(2.45m)�(73.0kg)(9.80m/s�1.75kJ87.AstuntwomanfindsthatshecansafelyKEiPEiKEfPEfbreakherfallfromaone-storybuildingbylandinginaboxfilledtoa1-mdepthwithYes.Themechanicalenergyhasfoampeanuts.Inhernextmovie,thescriptchanged,increaseinpotentialcallsforhertojumpfromafive-storybuild-energyof(635N)(5.0m)�3200J.ing.Howdeepaboxoffoampeanutsb.Wheredidthisenergycomefrom?shouldsheprepare?fromtheinternalenergyofthepersonAssumethatthefoampeanutsexertaconstantforcetoslowhimdown,MixedReviewW�Fd�E�mgh.Iftheheightispages309–310increasedfivetimes,thenthedepthofthefoampeanutsalsoshouldbeLevel1increasedfivetimesto5m.84.Supposeachimpanzeeswingsthroughthejungleonvines.IfitswingsfromatreeonaLevel213-m-longvinethatstartsatanangleof88.FootballA110-kgfootballlinebackerhasa45°,whatisthechimp’svelocitywhenithead-oncollisionwitha150-kgdefensivereachestheground?end.Aftertheycollide,theycometoaThechimpanzee’sinitialheightiscompletestop.Beforethecollision,whichCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.h�(13m)(1�cos45°)�3.8mplayerhadthegreatermomentumandConservationofmechanicalenergy:whichplayerhadthegreaterkineticenergy?�PE��KE�0Themomentumafterthecollisioniszero;therefore,thetwoplayershadmg(h�12�v2)�0f�hi)�2m(vfiequalandoppositemomentabeforethecollision.Thatis,�mgh�12�0i�2mvfplinebacker�mlinebackervlinebacker�pend2)�mvf��2�ghi��2(9.80��m/s(3.8m�)�endvend.Afterthecollision,eachhad�8.6m/szeroenergy.Theenergylossforeach12�1m2v2p2playerwas�mv������.85.An0.80-kgcartrollsdownafrictionlesshill22m2mofheight0.32m.Atthebottomofthehill,Becausethemomentawereequalbutthecartrollsonaflatsurface,whichexertsmlinebackermendthelinebackerlostafrictionalforceof2.0Nonthecart.Howfardoesthecartrollontheflatsurfacemoreenergy.beforeitcomestoastop?89.A2.0-kglabcartanda1.0-kglabcartareE�mgh�W�Fdheldtogetherbyacompressedspring.Themgh(0.80kg)(9.80m/s2)(0.32m)labcartsmoveat2.1m/sinonedirection.d�������F2.0NThespringsuddenlybecomesuncompressed�1.3mandpushesthetwolabcartsapart.The2-kg264SolutionsManualPhysics:PrinciplesandProblems
268Chapter11continuedlabcartcomestoastop,andthe1.0-kglab91.An0.80-kgcartrollsdowna30.0°hillfromcartmovesahead.Howmuchenergydidtheaverticalheightof0.50masshowninspringaddtothelabcarts?Figure11-22.ThedistancethatthecartE�12��1(2.0kg�1.0kg)(2.1m/s)2mustrolltothebottomofthehillisi�2mv20.50m/sin30.0°�1.0m.Thesurfaceofthe�6.6Jhillexertsafrictionalforceof5.0Nonthecart.Doesthecartrolltothebottomofthehill?pi�mv�(2.0kg�1.0kg)(2.1m/s)m�0.80kg�6.3kgm/s�pf�(1.0kg)vfF�5.0Nso,vf�6.3m/sE�12��1(1.0kg)(6.3m/s)2�19.8Jf�2mvf20.50m�E�19.8J�6.6J�13.2J30.0°13.2Jwasaddedbythespring.■Figure11-22E2)(0.50m)90.A55.0-kgscientistropingthroughthetopofi�mgh�(0.80kg)(9.80m/satreeinthejungleseesalionaboutto�3.9Jattackatinyantelope.ShequicklyswingsTheworkdonebyfrictionover1.0mdownfromher12.0-m-highperchandgrabswouldbetheantelope(21.0kg)assheswings.TheyW�Fd�(5.0N)(1.0m)�5.0J.barelyswingbackuptoatreelimboutofreachofthelion.Howhighisthistreelimb?Theworkdonebyfrictionisgreaterthantheenergyofthecart.ThecartEi�mBghwouldnotreachthebottomofthehill.ThevelocityofthebotanistwhenshereachesthegroundisLevel3E�12�m92.ObjectA,slidingonafrictionlesssurfaceati�2mBvBgh3.2m/s,hitsa2.0-kgobject,B,whichis2Ei2mBghmotionless.ThecollisionofAandBiscom-v����������2�ghmmBpletelyelastic.Afterthecollision,AandBmoveawayfromeachotheratequalandMomentumisconservedwhentheoppositespeeds.WhatisthemassofobjectA?botanistgrabstheantelope.pmi�mAv1�0Bv�(mB�mA)vfmBvmBpf�mA(�v2)�mBv2so,vf����(m����m�2�ghB�mA)B�mApi�pf(conservationofmomentum)Thefinalenergyofthetwoistherefore,m2Av1�mA(�v2)�mBv12E�f�2(mB�mA)vf(mB�mA)v2�mAv11mB2��(mB�mA)����(2gh)(mAv1)2mB�mAv2���(mB�mA)�(mB�mA)ghf12Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mEi��2mAv1B2So,h��hf���m1B�mAE�2��1m2f�2mAv22Bv255.0kg2������(12.0m)55.0kg�21.0kg�6.28mPhysics:PrinciplesandProblemsSolutionsManual265
269Chapter11continued12Fromtheconservationofmomentum,E�f�2(mA�mB)v2mcvc1�mcvc2�mbvb21(mAv1)2��2(mA�mB)����(mmbvb2B�mA)Solveforvc2,vc2�vc1��mcEi�Ef(conservationofenergyinFromconservationofenergy,elasticcollision)therefore,�1m2��1m2��1m22cvc12cvc22bvb2�1m2��1(m2Av12A�mB)Multiplybytwoandsubstitutetoget:(mAv1)22�mmbvb222����mcvc1c�vc1��m��mbvb2(mB�mA)cAftercancellingoutcommonfactors,orm2�m2�2mcvc1cvc1bvc2vc1�(m2�m2v2A�mB)mA�(mB�mA)bb22���mm2�2m2mcbvb2BAmB�mAmSimplifyandfactor:B2.00kgmA���3�3�0.67kgm2vbb20�(m���vbvb2)��2vc1�mb2�93.HockeyA90.0-kghockeyplayermovingatc5.0m/scollideshead-onwitha110-kgmbvb2�0orhockeyplayermovingat3.0m/sinthem�2v�boppositedirection.Afterthecollision,theyc1��m�1�vb2�0cmoveofftogetherat1.0m/s.Howmuchenergywaslostinthecollision?Ignoringthesolutionvb2�0,thenBefore:E��1mv2��1mv22vc12122vb2��m����b�1�m��1(90.0kg)(5.0m/s)2�c2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2(44m/s)����73m/s�1(110kg)(3.0m/s)2��0.046�kg�1�20.220kg�1.6�103J195.ApplyConceptsAflyhittingthewind-After:E��(m�m)v22fshieldofamovingpickuptruckisanexam-1pleofacollisioninwhichthemassofone��(200.0kg)(1.0m/s)22oftheobjectsismanytimeslargerthanthe�1.0�102Jother.Ontheotherhand,thecollisionoftwobilliardballsisoneinwhichthemassesEnergyloss�1.6�103J�1.0�102Jofbothobjectsarethesame.Howisenergy�1.5�103Jtransferredinthesecollisions?Consideranelasticcollisioninwhichbilliardballm1hasvelocityvThinkingCritically1andballm2ismotionless.a.Ifmpage3101�m2,whatfractionoftheinitialenergyistransferredtom94.ApplyConceptsAgolfballwithamassof2?0.046kgrestsonatee.ItisstruckbyagolfIfm1�m2,weknowthatm1willbeclubwithaneffectivemassof0.220kgandatrestafterthecollisionandm2willaspeedof44m/s.Assumingthatthecolli-movewithvelocityv1.Allofthesioniselastic,findthespeedoftheballenergywillbetransferredtom2.whenitleavesthetee.266SolutionsManualPhysics:PrinciplesandProblems
270Chapter11continuedb.Ifm1��m2,whatfractionoftheinitialenergyistransferredtom2?Ifm1m2,weknowthatthemotionofm1willbeunaffectedbythecollisionandthattheenergytransfertom2willbeminimal.c.Inanuclearreactor,neutronsmustbesloweddownbycausingthemtocollidewithatoms.(Aneutronisaboutasmassiveasaproton.)Wouldhydrogen,carbon,orironatomsbemoredesirabletouseforthispurpose?Thebestwaytostopaneutronistohaveithitahydrogenatom,whichhasaboutthesamemassastheneutron.96.AnalyzeandConcludeInaperfectlyelasticcollision,bothmomentumandmechanicalenergyareconserved.Twoballs,withmassesmAandmB,aremovingtowardeachotherwithspeedsvAandvB,respectively.Solvetheappropriateequationstofindthespeedsofthetwoballsafterthecollision.conservationofmomentum(1)mAvA1�mBvB1�mAvA2�mBvB2mAvA1�mAvA2��mBvB1�mBvB2(2)mA(vA1�vA2)��mB(vB1�vB2)conservationofenergy�1m2��1m2��1m2��1m22AvA12BvB12AvA22BvB2m2�m2��m2�m2AvA1AvA2BvB1BvB2m2�v2)��m2�v2)A(vA1A2B(vB1B2(3)mA(vA1�vA2)(vA1�vA2)��mB(vB1�vB2)(vB1�vB2)Divideequation(3)by(2)toobtain(4)vA1�vA2�vB1�vB2Solveequation(1)forvA2andvB2mBv�A2�vA1�m(vB1�vB2)AmAv��(vB2�vB1�mA1�vA2)BSubstituteinto(4)andsolveforvB2andvA2mBv�A1�vA1�m(vB1�vB2)�vB1�vB2A2mAvA1�mBvB1�mBvB2�mAvB1�mAvB22mAmB�mAv����B2���mvA1���mvB1A�mBA�mBCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mAv��(vA1�vA2�vB1�vB1�mA1�vA2)BmBvA1�mBvA2�2mBvB1�mAvA1�mAvA2mA�mB2mBv����A2���mvA1���mvB1A�mBA�mBPhysics:PrinciplesandProblemsSolutionsManual267
271Chapter11continued97.AnalyzeandConcludeA25-gballisfiredwithaninitialspeedofv1towarda125-gballthatishangingmotionlessfroma1.25-mstring.Theballshaveaperfectlyelasticcollision.Asaresult,the125-gballswingsoutuntilthestringmakesanangleof37.0°withthevertical.Whatisv1?Object1istheincomingball.Object2istheoneattachedtothestring.Inthecollision,momentumisconserved.p1i�p1f�p2form1v1i�m1v1f�m2v2fInthecollision,kineticenergyisconserved.�1m2��1m2��1m221v1i21v1f22v2fm2�m2�m21v1i1v1f2v2fmmm(m2)���12)�12)�21v1im�(m1v1f��m�(m2v2f��m112m2v2m2v2m2v211i11f22f�������m1m1m2p2p2p21i1f2f�������mmm112mp2�p2����1�21i1fmp2f2Wedon’tcareaboutv1f,sogetridofp1fusingp1f�p1i�p2fmp2�(p2��1p21i1i�p2f)m2f2m2�p2�2p2�1p2p1i1i1ip2f�p2f�2fCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.m2m122p�1ip2f��1�m�p2f21m1p1i���2���1��m�p2f21m1v1i���2��(m2�m1)v2f1m2v1i���2����m�1�v2f1Nowconsiderthependulum.�1m2�m22v2f2ghorv2f��2�ghwhereh�L(1�cos�)Thus,v2f��2�gL(1��co�s�)v2f��(2)(9.8�0m/s�2)(1.25�m)(1���cos37.0�°)�2.22m/s268SolutionsManualPhysics:PrinciplesandProblems
272Chapter11continued1125gmakemoleculesandreleasedwhenthev��1i�2�25g�1�(2.22m/s)moleculesarebrokenuporrearranged.Separationofelectricchargesproduces�6.7m/selectricpotentialenergy,asinabattery.ElectricpotentialenergyisconvertedtoWritinginPhysicskineticenergyinthemotionofelectricpage310chargesinanelectriccurrentwhenacon-98.AllenergycomesfromtheSun.Inwhatformsductivepath,orcircuit,isprovided.hasthissolarenergycometoustoallowustoBiologicalprocessesareallchemical,andliveandtooperateoursociety?Researchthethus,biologicalenergyisjustaformofwaysthattheSun’senergyisturnedintoachemicalenergy.Solarenergyisfusionformthatwecanuse.AfterweusetheSun’senergyconvertedtotoelectromagneticenergy,wheredoesitgo?Explain.radiation.(SeetheanswertothepreviousTheSunproducesenergythroughquestion.)Lightisawaveformofelectro-nuclearfusionandreleasesthatenergymagneticenergywhosefrequencyisinaintheformofelectromagneticradiation,rangedetectiblebythehumaneye.whichistransferredthroughthevacu-umofspacetoEarth.EarthabsorbsCumulativeReviewthatelectromagneticradiationinitspage310atmosphere,land,andoceansinthe100.Asatelliteisplacedinacircularorbitwithformofthermalenergyorheat.Partof7mandaperiodofaradiusof1.0�10thevisibleradiationalsoisconverted3s.CalculatethemassofEarth.9.9�10byplantsintochemicalenergythroughHint:Gravityisthenetforceonsuchasatel-photosynthesis.Thereareseveralotherlite.Scientistshaveactuallymeasuredthechemicalreactionsmediatedbysun-massofEarththisway.(Chapter7)light,suchasozoneproduction.Them2GmenergythenistransferredintovarioussvsmeF��net��rr2forms,someofwhicharethechemicalprocessesthatallowustodigestfood2�rSince,v���Tandturnitintochemicalenergytobuildtissues,tomove,andtothink.Inthems4�2r2Gmsme���r��T�2���r2end,afterwehaveusedtheenergy,theremainderisdispersedaselectromag-4�2r2neticradiationbackintotheuniverse.me��GT24�2(1.0�107m)399.Allformsofenergycanbeclassifiedas������(6.67�10�11Nm2/kg2)(9.9�10s)2eitherkineticorpotentialenergy.How�6.0�1024kgwouldyoudescribenuclear,electric,chemi-cal,biological,solar,andlightenergy,and101.A5.00-gbulletisfiredwithavelocityofwhy?Foreachofthesetypesofenergy,100.0m/stowarda10.00-kgstationaryresearchwhatobjectsaremovingandhowsolidblockrestingonafrictionlesssurface.energyisstoredinthoseobjects.(Chapter9)Potentialenergyisstoredinthebindinga.Whatisthechangeinmomentumofoftheprotonsandneutronsinthenucle-thebulletifitisembeddedintheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.us.Theenergyisreleasedwhenaheavyblock?nucleusisbrokenintosmallerpieces(fis-sion)orwhenverysmallnucleiarecom-mbvb1�mbv2�mwv2binedtomakebiggernuclei(fusion).In�(mb�mw)v2thesameway,chemicalpotentialenergyisstoredwhenatomsarecombinedtoPhysics:PrinciplesandProblemsSolutionsManual269
273Chapter11continuedmsov��bvb1IMA2)(33cm)2�mde���d(2.0�10b�mwrThen,�66m�pv�mb(v2�vb1)mbvb1�mb���m�vb1�ChallengeProblemb�mwmpage300b�mbvb1���m�1�Abulletofmassm,movingatspeedv1,goesb�mwthroughamotionlesswoodenblockandexitsm����bmwvwithspeedvmb12.Afterthecollision,theblock,b�mwwhichhasmassmB,ismoving.(5.00�10�3kg)(10.00kg)������5.00�10�3kg�10.00kgInitialFinal(100.0m�s)v1v2��0.500kg�m/svBb.Whatisthechangeinmomentumofthebulletifitricochetsintheoppositedirectionwithaspeedof99m/s?�pv�mb(v2�vb1)�(5.00�10�3kg)1.WhatisthefinalspeedvB,oftheblock?Conservationofmomentum:(�99.0m/s�100.0m/s)mv��0.995kgm/s1�mv2�mBvBc.InwhichcasedoestheblockendupmBvB�m(v1�v2)withagreaterspeed?m(v1�v2)v��Whenthebulletricochets,itsB�mBCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.changeinmomentumislargerinmagnitude,andsoistheblock’s2.Howmuchenergywaslosttothebullet?changeinmomentum,sotheblockForthebulletalone:endsupwithagreaterspeed.12KE�1�2mv1102.Anautomobilejackmustexertalifting12forceofatleast15kN.KE2��2mv2a.Ifyouwanttolimittheeffortforceto�KE��1m(v2�v2)0.10kN,whatmechanicaladvantageis212needed?3.Howmuchenergywaslosttofrictioninside15kNMA����150theblock?0.10kNEnergylosttofriction�KEb.Ifthejackis75%efficient,overwhat1�distancemusttheeffortforcebeexertedKE2�KEblockinordertoraisetheauto33cm?E�12��1mv2��1m2IMA�M�A�2.0�102.lost�2mv1222BvB�edSince�e�IMA,dr270SolutionsManualPhysics:PrinciplesandProblems
274CHAPTER12ThermalEnergypage319PracticeProblems3.Whenyouturnonthehotwatertowash12.1Temperatureanddishes,thewaterpipeshavetoheatup.ThermalEnergyHowmuchheatisabsorbedbyacopperwaterpipewithamassof2.3kgwhenitspages313–322temperatureisraisedfrom20.0°Ctopage31780.0°C?1.ConvertthefollowingKelvintemperaturesQ�mC�TtoCelsiustemperatures.�(2.3kg)(385J/kg�K)a.115K(80.0°C�20.0°C)TC�TK�273�115�273��158°C�5.3�104Jb.172K4.ThecoolingsystemofacarenginecontainsTC�TK�273�172�273��101°C20.0Lofwater(1Lofwaterhasamassofc.125K1kg).TC�TK�273�125�273��148°Ca.Whatisthechangeinthetemperatured.402Kofthewateriftheengineoperatesuntil836.0kJofheatisadded?TC�TK�273�402�273�129°CQ�mC�Te.425KQ(8.36�105J)TC�TK�273�425�273�152°C�T�������mC(20.0kg)(4180J/kg�K)f.212K�10.0KTC�TK�273�212�273��61°Cb.Supposethatitiswinter,andthecar’s2.FindtheCelsiusandKelvintemperaturescoolingsystemisfilledwithmethanol.forthefollowing.Thedensityofmethanolis0.80g/cm3.a.roomtemperatureWhatwouldbetheincreaseintempera-tureofthemethanolifitabsorbedRoomtemperatureisabout72°F,836.0kJofheat?22°C.ThemassofmethanolwouldbeTK�TC�273�22�273�295K0.80timesthemassof20.0Lofb.atypicalrefrigeratorwater,or16kg.Arefrigeratoriskeptatabout4°C.Q�mC�TTK�TC�273�4�273�277K5JQ8.36�10c.ahotsummerdayinNorthCarolina�T�������mC(16kg)(2450J/kg�K)Ahotsummerdayisabout95°F,�21K35°C.c.Whichisthebettercoolant,waterorCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.TK�TC�273�35�273�308Kmethanol?Explain.d.awinternightinMinnesotaFortemperaturesabove0°C,waterAtypicalwinternightinMinnesotaisthebettercoolantbecauseitcanisabout14°F,�10°C.absorbheatwithoutchangingitstem-TK�TC�273��10�273�263Kperatureasmuchasmethanoldoes.Physics:PrinciplesandProblemsSolutionsManual271
275Chapter12continued5.ElectricpowercompaniessellelectricitybythekWh,where1kWh�3.6�106J.Supposethatitcosts$0.08perkWhtorunanelectricwaterheaterinyourneigh-borhood.Howmuchdoesitcosttoheat75kgofwaterfrom15°Cto43°Ctofillabathtub?Q�mC�T�(75kg)(4180J/kg�K)(43°C�15°C)�8.8�106J8.8�106J���2.4kWh3.6�106J/kWh(2.4kWh)($0.15perkWh)�$0.36page3216.A2.00�102-gsampleofwaterat80.0°Cismixedwith2.00�102gofwaterat10.0°C.Assumethatthereisnoheatlosstothesurroundings.Whatisthefinaltemperatureofthemixture?mACA(Tf�TAi)�mBCB(Tf�TBi)�0SincemA�mBandCA�CB,thereiscancellationinthisparticularcasesothatTT80.0°C�10.0°CT�Ai��Bi����45.0°Cf�227.A4.00�102-gsampleofmethanolat16.0°Cismixedwith4.00�102gofwaterat85.0°C.Assumethatthereisnoheatlosstothesurroundings.Whatisthefinaltemperatureofthemixture?mACA(Tf�TAi)�mWCW(Tf�TWi)�0Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Sinceinthisparticularcase,mA�mW,themassescancelandCATAi�CWTWiT��f�CA�CW(2450J/kg�K)(16.0°C)�(4180J/kg�K)(85.0°C)��������59.5°C2450J/kg�K�4180J/kg�K8.Threeleadfishingweights,eachwithamassof1.00�102gandatatemperatureof100.0°C,areplacedin1.00�102gofwaterat35.0°C.Thefinaltemperatureofthemixtureis45.0°C.Whatisthespecificheatoftheleadintheweights?Heatgainedbythewater:Q�mC�T�(0.100kg)(4180J/kg�°C)(10.0°C)�4.18kJThus,heatlostbytheweights��4.18kJ�mweightsCweights�T(�4.184kJ)(1000J/kJ)hence,C���weights�(0.100kg)(�55.0°C)�2.53�102J/kg�°C272SolutionsManualPhysics:PrinciplesandProblems
276Chapter12continued9.A1.00�102-galuminumblockat100.0°Cd.�55°Cisplacedin1.00�102gofwaterat10.0°C.218KThefinaltemperatureofthemixtureise.�184°C25.0°C.Whatisthespecificheatofthe89Kaluminum?Heatgainedbythewater:12.ThermalEnergyCouldthethermalenergyQ�mC�Tofabowlofhotwaterequalthatofabowl�(0.100kg)(4180J/kg�°C)(15.0°C)ofcoldwater?Explainyouranswer.Thermalenergyisthemeasureofthe�6.27kJtotalenergyofallthemoleculesinanThus,heatlostbythealuminumblockobject.Thetemperature(hotorcold)��6.27kJ�mAluminumCAluminum�TmeasurestheamountofenergyperQmolecule.Ifthebowlsareidenticalandhence,C��Aluminum�mAluminum�Tcontainthesameamountofwater,theyhavethesamenumberofmolecules,�6.27kJ����butthebowlofhotwaterhasmore(0.100kg)(�75.0°C)totalthermalenergy.However,ifthe�8.36�102J/kg�°Ccoldwatermassisslightlymorethanthatofthehotwater,thetwoenergiescouldbeequal.SectionReview12.1Temperatureand13.HeatFlowOnadinnerplate,abakedpotatoalwaysstayshotlongerthananyThermalEnergyotherfood.Why?pages313–322Apotatohasalargespecificheatandpage322conductsheatpoorly,soitlosesits10.TemperatureMakethefollowingheatenergyslowly.conversions.a.5°Ctokelvins14.HeatThehardtilefloorofabathroom278Kalwaysfeelscoldtobarefeeteventhoughtherestoftheroomiswarm.Isthefloorb.34KtodegreesCelsiuscolderthantherestoftheroom?�239°CThefloorisusuallyatthesametempera-c.212°Ctokelvinstureastherestoftheroom,butthetile485Kconductsheatmoreefficientlythanmostd.316KtodegreesCelsiusmaterials,soitconductsheatfromaperson’sfeet,makingthemfeelcold.43°C15.SpecificHeatIfyoutakeaplasticspoon11.ConversionsConvertthefollowingoutofacupofhotcocoaandputitinyourCelsiustemperaturestoKelvinmouth,youarenotlikelytoburnyourtemperatures.tongue.However,youcouldveryeasilya.28°CburnyourtongueifyouputthehotcocoaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.301Kinyourmouth.Why?b.154°CTheplasticspoonhasalowerspecific427Kheatthanthecocoa,soitdoesnotc.568°Ctransmitmuchheattoyourtongueasitcools.841KPhysics:PrinciplesandProblemsSolutionsManual273
277Chapter12continued16.HeatChefsoftenusecookingpansmadeofthickaluminum.Whyisthickalu-minumbetterthanthinaluminumforcooking?Thickaluminumconductsheatbetteranddoesnothaveany“hotspots.”17.HeatandFoodIttakesmuchlongertobakeawholepotatothantocookfrenchfries.Why?Potatoesdonotconductheatwell.Increasingsurfaceareabycuttingapotatointosmallpartsincreasesheatflowintothepotato.Heatflowfromhotoiltothepotatoisalsomoreefficientthanfromhotair.18.CriticalThinkingAswaterheatsinapotonastove,thewatermightproducesomemistaboveitssurfacerightbeforethewaterbeginstoroll.Whatishappen-ing,andwhereisthecoolestpartofthewaterinthepot?Theheatflowsfromtheburner(thehottestpart)tothetopsurfaceofthewater(coldest).Thewaterfirsttransfersheatfrombottomtotopthroughconduction,andthenconvectionbeginstomovehotwaterincurrentstothetop.PracticeProblems12.2ChangesofStateandtheLawsofThermodynamicspages323–331page32519.Howmuchheatisabsorbedby1.00�102goficeat�20.0°Ctobecomewaterat0.0°C?Q�mC�T�mHfCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(0.100kg)(2060J/kg�°C)(20.0°C)�(0.100kg)(3.34�105J/kg)�3.75�104J20.A2.00�102-gsampleofwaterat60.0°Cisheatedtosteamat140.0°C.Howmuchheatisabsorbed?Q�mCwater�T�mHv�mCsteam�T�(0.200kg)(4180J/kg�°C)(100.0°C�60.0°C)�(0.200kg)(2.26�106J/kg)�(0.200kg)(2020J/kg�°C)(140.0°C�100.0°C)�502kJ21.Howmuchheatisneededtochange3.00�102goficeat�30.0°Ctosteamat130.0°C?Q�mCice�T�mHf�mCwater�T�mHv�mCsteam�T�(0.300kg)(2060J/kg�°C)(0.0°C�(�30.0°C))�(0.300kg)(3.34�105J/kg)�(0.300kg)(4180J/kg�°C)(100.0°C�0.0°C)�(0.300kg)(2.26�106J/kg)�(0.300kg)(2020J/kg�°C)(130.0°C�100.0°C)�9.40�102kJ274SolutionsManualPhysics:PrinciplesandProblems
278Chapter12continuedpage328�(0.15kg)(4180J/kg�°C)(2.0°C)22.Agasballoonabsorbs75Jofheat.Thebal-�1.3�103J.loonexpandsbutstaysatthesametemper-ature.HowmuchworkdidtheballoondoThenumberofstirsisinexpanding?1.3�103J4stirs���2.6�10�U�Q�W0.050JSincetheballoondidnotchange26.Howcanthefirstlawofthermodynamicstemperature,�U�0.beusedtoexplainhowtoreducetheTherefore,Q�W.temperatureofanobject?Thus,theballoondid75JofworkinSince�U�Q�W,itispossibletoexpanding.haveanegative�Uandtherefore,coolanobjectifQ�0andtheobjectdoes23.Adrillboresasmallholeina0.40-kgblockwork,forinstance,byexpanding.ofaluminumandheatsthealuminumbyAlternatively,haveW�0andQ5.0°C.Howmuchworkdidthedrilldoinnegativebyhavingittransferheattoboringthehole?itssurroundings.Anycombinationof�U�Q�Wblock;sinceWdrill��Wblockthesewillworkwell.andassumenoheataddedtodrill:�0�Wdrill�mC�TSectionReview�(0.40kg)(897J/kg�°C)(5.0°C)12.2ChangesofStateandthe�1.8�103JLawsofThermodynamicspages323–33124.Howmanytimeswouldyouhavetodropapage3310.50-kgbagofleadshotfromaheightof27.HeatofVaporizationOld-fashionedheat-1.5mtoheattheshotby1.0°C?ingsystemssentsteamintoradiatorsineach�U�mC�Troomofahouse.Intheradiators,thesteam�(0.50kg)(130J/kg�°C)(1.0°C)condensedbacktowater.Analyzethis�65Jprocessandexplainhowitheatedaroom.EachtimethebagisraiseditspotentialThecondensingsteamreleaseditsheatenergyisofvaporizationintotheroomandwasthencirculatedbacktotheboilertoPE�mghreceivetheheatofvaporizationagain.�(0.50kg)(9.80m/s2)(1.5m)�7.4J28.HeatofVaporizationHowmuchheatisWhenthebaghitsthegroundthisneededtochange50.0gofwaterat80.0°Cenergyis(mostly)transmittedasworktosteamat110.0°C?ontheleadshot.ThenumberofdropsQ�mCwater�T�mHv�mCsteam�T65Jis���9drops7.4J�(0.500kg)(4180J/kg�°C)(100.0°C�80.0°C)�(0.500kg)25.Whenyoustiracupoftea,youdoaboutCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.0.050Jofworkeachtimeyoucirclethe(2.26�106J/kg)�(0.500kg)spooninthecup.Howmanytimeswould(2020J/kg�°C)(110.0°C�100.0°C)youhavetostirthespoontoheata0.15-kgcupofteaby2.0°C?�1.18�105J�U�mC�TPhysics:PrinciplesandProblemsSolutionsManual275
279Chapter12continued29.HeatofVaporizationThespecificheat32.MechanicalEnergyandThermalEnergyofmercuryis140J/kg�°C.Itsheatofvapor-Waterflowsoverafallthatis125.0mhigh,izationis3.06�105J/kg.HowmuchenergyasshowninFigure12-17.Ifthepotentialisneededtoheat1.0kgofmercurymetalenergyofthewaterisallconvertedtother-from10.0°Ctoitsboilingpointandmalenergy,calculatethetemperaturediffer-vaporizeitcompletely?Theboilingpointencebetweenthewateratthetopandtheofmercuryis357°C.bottomofthefall.Q�mCHg�T�mHv�(1.0kg)(140J/kg�°C)(357°C�10.0°C)�125.0m(1.0kg)(3.06�105J/kg)�3.5�105J30.MechanicalEnergyandThermalEnergyJamesJoulecarefullymeasuredthediffer-■Figure12-17enceintemperatureofwateratthetopandPEgravity�Qabsorbedbywaterbottomofawaterfall.Whydidheexpectamgh�mC�Tdifference?Thewateratthetophasgravitationalgh�T���potentialenergythatisdissipatedintoCthermalenergywhenthewatersplash-(9.80m/s2)(125.0m)����esatthebottom.Thewatershouldbe4180J/kg�°Chotteratthebottom,butnotbymuch.�0.293°Criseintemperatureatthebottom31.MechanicalEnergyandThermalEnergyAmanusesa320-kghammermovingat33.EntropyEvaluatewhyheatingahomeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.5.0m/stosmasha3.0-kgblockofleadwithnaturalgasresultsinanincreasedagainsta450-kgrock.Whenhemeasuredamountofdisorder.thetemperaturehefoundthatithadThegasreleasesheat,Q,atitscombus-increasedby5.0°C.Explainhowthistiontemperature,T.Thenaturalgashappened.moleculesbreakupandcombustwithPartofthekineticenergyofthehammeroxygen.Theheatisdistributedinmanyisabsorbedasthermalenergybythenewways,andthenaturalgasmoleculesleadblock.Thehammer’senergyiscannotreadilybereassembled.�1�mv2��1�(320kg)(5.0m/s)2�4.0kJ.22Thechangeinthermalenergyofthe34.CriticalThinkingAnewdeckofcardshasblockisallthesuits(clubs,diamonds,hearts,andspades)inorder,andthecardsareordered�U�mC�Tbynumberwithinthesuits.Ifyoushuffle�(3.0kg)(130J/kg�K)(5.0°C)thecardsmanytimes,areyoulikelyto�2.0kJreturnthecardstotheiroriginalorder?Hence,abouthalfofthehammer’sExplain.Ofwhatphysicallawisthisanenergywenttotheleadblock.example?Thecardsareveryunlikelytoreturntotheiroriginalorder.Thisisanexampleofthesecondlawofthermodynamics,inwhichdisorderincreases.276SolutionsManualPhysics:PrinciplesandProblems
280Chapter12continued40.WhenheatflowsfromawarmerobjectinChapterAssessmentcontactwithacolderobject,dothetwoConceptMappinghavethesametemperaturechanges?(12.1)page336Thetwoobjectswillchangetempera-35.Completethefollowingconceptmapusingturesdependingontheirmassesandthefollowingterms:heat,work,internalenergy.specificheats.Thetemperaturechangesarenotnecessarilythesameforeach.Firstlawofthermodynamics41.Canyouaddthermalenergytoanobjectwithoutincreasingitstemperature?Explain.(12.2)heatworkinternalWhenyoumeltasolidorboilaenergyliquid,youaddthermalenergywithoutchangingthetemperature.externalentropytemperatureforces42.Whenwaxfreezes,doesitabsorborreleaseenergy?(12.2)MasteringConceptsWhenwaxfreezes,itreleasesenergy.page33636.Explainthedifferencesamongthemechani-43.Explainwhywaterinacanteenthatissur-calenergyofaball,itsthermalenergy,androundedbydryairstayscoolerifithasaitstemperature.(12.1)canvascoverthatiskeptwet.(12.2)ThemechanicalenergyisthesumofWhenthewaterinthecoverevaporatesthepotentialandkineticenergiesoftheintothedryair,itmustabsorbanballconsideredasonemass.Thether-amountofenergyproportionaltoitsmalenergyisthesumofthepotentialheatoffusion.Indoingso,itcoolsoffandkineticenergiesoftheindividualthecanteen.Thisworksonlyiftheairparticlesthatmakeupthemassoftheisdry;iftheairishumid,thenthewaterball.Thetemperatureisameasureofwillnotevaporate.theinternalenergyoftheball.44.Whichprocessoccursatthecoilsofarun-37.Cantemperaturebeassignedtoavacuum?ningairconditionerinsideahouse,vapor-Explain.(12.1)izationorcondensation?Explain.(12.2)No,becausetherearenoparticlesthatInsidethehouse,thecoolantisevapo-haveenergyinavacuum.ratinginthecoilstoabsorbenergyfromtherooms.38.Doallofthemoleculesoratomsinaliquidhavethesamespeed?(12.1)ApplyingConceptsNo.Thereisadistributionofvelocitiespage336oftheatomsormolecules.45.CookingSallyiscookingpastainapotofboilingwater.Willthepastacookfasterif39.Isyourbodyagoodjudgeoftemperature?thewaterisboilingvigorouslyorifitisOnacoldwinterday,ametaldoorknobfeelsboilinggently?muchcoldertoyourhandthanawoodenCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Itshouldmakenodifference.Eitherway,doordoes.Explainwhythisistrue.(12.1)thewaterisatthesametemperature.Yourskinmeasuresheatflowtoorfromitself.Themetaldoorknobabsorbsheatfromyourskinfasterthanthewoodendoor,soitfeelscolder.Physics:PrinciplesandProblemsSolutionsManual277
281Chapter12continued46.Whichliquidwouldanicecubecoolfaster,MasteringProblemswaterormethanol?Explain.12.1TemperatureandThermalEnergyMethanol,becauseithasalowerpages336–337specificheat;foragivenmassandheatLevel1transfer,itgeneratesabigger�Tsince52.HowmuchheatisneededtoraisetheQ�mC�T.temperatureof50.0gofwaterfrom4.5°Cto83.0°C?47.Equalmassesofaluminumandleadareheatedtothesametemperature.ThepiecesQ�mC�Tofmetalareplacedonablockofice.Which�(0.0500kg)(4180J/kg�°C)metalmeltsmoreice?Explain.(83.0°C�4.5°C)Thespecificheatofaluminumismuchgreaterthanthatoflead;therefore,it�1.64�104Jmeltsmoreice.53.A5.00�102-gblockofmetalabsorbs5016J48.Whydoeasilyvaporizedliquids,suchasofheatwhenitstemperaturechangesfromacetoneandmethanol,feelcooltotheskin?20.0°Cto30.0°C.Calculatethespecificheatofthemetal.Astheyevaporate,theyabsorbtheirheatofvaporizationfromtheskin.Q�mC�TQsoC���49.Explainwhyfruitgrowersspraytheirtreesm�Twithwaterwhenfrostisexpectedtoprotect5016J�����thefruitfromfreezing.(5.00�10�1kg)(30.0°C�20.0°C)Thewaterontheleaveswillnotfreeze�1.00�103J/kg�°Cuntilitcanreleaseitsheatoffusion.Thisprocesskeepstheleaveswarmer�1.00�103J/kg�Klonger.Theheatcapacityoftheiceslowsdownthecoolingbelow0°C.54.CoffeeCupA4.00�102-gglasscoffeecupCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.is20.0°Catroomtemperature.Itisthen50.Twoblocksofleadhavethesametempera-plungedintohotdishwateratatempera-ture.BlockAhastwicethemassofblockB.tureof80.0°C,asshowninFigure12-18.TheyaredroppedintoidenticalcupsofIfthetemperatureofthecupreachesthatofwaterofequaltemperatures.Willthetwothedishwater,howmuchheatdoesthecupcupsofwaterhaveequaltemperaturesafterabsorb?Assumethatthemassofthedish-equilibriumisachieved?Explain.waterislargeenoughsothatitstempera-ThecupwithblockAwillbehotterturedoesnotchangeappreciably.becauseblockAcontainsmorethermal20.0°C80.0°Cenergy.51.WindowsOften,architectsdesignmostofthewindowsofahouseonthenorthside.2Howdoesputtingwindowsonthesouthside4.00�10gaffecttheheatingandcoolingofthehouse?■Figure12-18Inthenorthernhemisphere,thesun-Q�mC�Tlightcomesfromthesouth.TheSun’s�(4.00�10�1kg)(840J/kg�°C)lightwouldhelpheatthehouseinthewinterbutalsowouldalsoheatthe(80.0°C�20.0°C)houseinthesummer.�2.02�104J278SolutionsManualPhysics:PrinciplesandProblems
282Chapter12continued55.A1.00�102-gmassoftungstenat100.0°Cisplacedin2.00�102gofwaterat20.0°C.Themixturereachesequilibriumat21.6°C.Calculatethespecificheatoftungsten.�QT��QW�0ormTCT�TT��mWCW�TW�mWCW�TW�(0.200kg)(4180J/kg�K)(21.6°C�20.0°C)C���������T�mT�TT(0.100kg)(21.6°C�100.0°C)�171J/kg�K56.A6.0�102-gsampleofwaterat90.0°Cismixedwith4.00�102gofwaterat22.0°C.Assumethatthereisnoheatlosstothesurroundings.Whatisthefinaltemperatureofthemixture?mACA�TAi�mBCB�TBiT���f�mACA�mBCBbutCA�CBbecausebothliquidsarewater,andtheC’swilldivideout.m(6.0�102g)(90.0°C)�(4.00�102g)(22.0°C)T��ATAi�mBTBi������f��mA�mB6.0�102g�4.00�102g�63°C57.A10.0-kgpieceofzincat71.0°Cisplacedinacontainerofwater,asshowninFigure12-19.Thewaterhasamassof20.0kganda20.0kgtemperatureof10.0°Cbeforethezincisadded.Whatisthefinalgktemperatureofthewaterand.00thezinc?110.0°CmT���ACA�TAi�mBCB�TBif�mACA�mBCB■Figure12-19(10.0kg)(388J/kg�K)(71.0°C)�(20.0kg)(4180J/kg�K)(10.0°C)���������(10.0kg)(388J/kg�K)�(20.0kg)(4180J/kg�K)�12.7°CLevel258.Thekineticenergyofacompactcarmovingat100km/his2.9�105J.Togetafeelingfortheamountofenergyneededtoheatwater,whatvolumeofwater(inliters)would2.9�105Jofenergywarmfromroomtemperature(20.0°C)toboiling(100.0°C)?Q�mC�T��VC�Twhere�isthedensityofthematerialCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Q2.9�105Jso,V�����������C�T(1.00kg/L)(4180J/kg�°C)(100.0°C�20.0°C)�0.87LPhysics:PrinciplesandProblemsSolutionsManual279
283Chapter12continued59.WaterHeaterA3.0�102-Welectric2immersionheaterisusedtoheatacup3.00�10Wofwater,asshowninFigure12-20.Thecupismadeofglass,anditsmassis3.00�102g.Itcontains250gofwaterat15°C.Howmuchtimeisneededtobringthewatertotheboilingpoint?Assume15°Cthatthetemperatureofthecupisthesameasthetemperatureofthewaterat250galltimesandthatnoheatislosttotheair.Q�mGCG�TG�mWCW�TW3.00�102gbut�TG��TW,so■Figure12-20Q�(mGCG�mWCW)�T�((0.300kg)(840J/kg�°C)�(0.250kg)(4180J/kg�°C))(100.0°C�15°C)�1.1�105JEQNowP������,sottQ1.1�105Jt������P3.00�102J/s�370s�6.1min60.CarEngineA2.50�102-kgcast-ironcarenginecontainswaterasacoolant.Supposethattheengine’stemperatureis35.0°Cwhenitisshutoff,andtheairtemperatureis10.0°C.Theheatgivenoffbytheengineandwaterinitastheycooltoairtemperatureis4.40�106J.Whatmassofwaterisusedtocooltheengine?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Q�mWCW�T�miCi�TQ�miCi�T(4.4�106J)�((2.50�102kg)(450J/kg�°C)(35.0°C�10.0°C))m����������W�C�T(4180J/kg�°C)(35.0°C�10.0°C)W�15kg12.2ChangesofStateandtheLawsofThermodynamicspage337Level161.Yearsago,ablockoficewithamassofabout20.0kgwasuseddailyinahomeicebox.Thetemperatureoftheicewas0.0°Cwhenitwasdelivered.Asitmelted,howmuchheatdidtheblockoficeabsorb?Q�mH5J/kg)�6.68�106Jf�(20.0kg)(3.34�1062.A40.0-gsampleofchloroformiscondensedfromavaporat61.6°Ctoaliquidat61.6°C.Itliberates9870Jofheat.Whatistheheatofvaporizationofchloroform?Q�mHvH�Q��9870J5J/kgv��m0.0400kg�2.47�10280SolutionsManualPhysics:PrinciplesandProblems
284Chapter12continued63.A750-kgcarmovingat23m/sbrakestoaQ�mC�Tstop.Thebrakescontainabout15kgofiron,�(0.0100kg)(2060J/kg�°C)whichabsorbstheenergy.Whatistheincreaseintemperatureofthebrakes?(120.0°C�100.0°C)Duringbraking,thekineticenergyof�404JthecarisconvertedintoheatThetotalheatisenergy.So,412J�3.34�103J�4.18�103J��KEC�QB�0.0,and�KEC�2.26�104J�404J�3.09�104JmBCB�T�0.0so,65.A4.2-gleadbulletmovingat275m/s�1�m2�v2)��KEC2C(vfistrikesasteelplateandcomestoastop.If�T�������mBCBmBCBallitskineticenergyisconvertedtothermalenergyandnoneleavesthebullet,whatis�1�(750kg)(0.02�(23m/s)2)itstemperaturechange?2������(15kg)(450J/kg�°C)Becausethekineticenergyisconvertedtothermalenergy,�KE�Q�0.So�29°C�KE��mBCB�TandLevel264.Howmuchheatisaddedto10.0goficeat��1�m2�v2)�KE2B(vfi�20.0°Ctoconvertittosteamat120.0°C?�T�������mBCBmBCBAmountofheatneededtoheaticetoandthemassofthebulletdividesoutso0.0°C:Q�mC�T��1�(v2�v2)2fi�T����(0.0100kg)(2060J/kg�°C)CB(0.0°C�(�20.0°C))��1�((0.0m/s)2�(275m/s)2)2�412J�����130J/kg�°CAmountofheattomeltice:�290°CQ�mHf�(0.0100kg)(3.34�105J/kg)66.SoftDrinkAsoftdrinkfromAustraliaislabeled“Low-JouleCola.”Thelabelsays�3.34�103J“100mLyields1.7kJ.”ThecancontainsAmountofheattoheatwaterto375mLofcola.Chandradrinksthecola100.0°C:andthenwantstooffsetthisinputoffoodQ�mC�Tenergybyclimbingstairs.HowhighwouldChandrahavetoclimbifshehasamassof�(0.0100kg)(4180J/kg�°C)65.0kg?(100.0°C�0.0°C)Chandragained(3.75)(1.7kJ)�6.4�103J�4.18�103Jofenergyfromthedrink.Amountofheattoboilwater:Toconserveenergy,E��PE�0or6.4�103J��mg�hso,Q�mHCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.v6.4�103J6.4�103J�(0.0100kg)(2.26�106J/kg)�h���m�g�����(65.0kg)(�9.80m/s2)�2.26�104J�1.0�101m,oraboutthreeflightsAmountofheattoheatsteamtoofstairs120.0°C:Physics:PrinciplesandProblemsSolutionsManual281
285Chapter12continuedMixedReview�KETherefore,�T���mCpages337–338Level14.7�105J����(45kg)(897J/kg�°C)67.Whatistheefficiencyofanenginethatpro-duces2200J/swhileburningenoughgaso-�12°Clinetoproduce5300J/s?Howmuchwasteheatdoestheengineproducepersecond?70.IcedTeaTomakeicedtea,youstartbybrewingtheteawithhotwater.ThenyouW2200JEfficiency���100����100addice.Ifyoustartwith1.0Lof90°Ctea,Q5300JHwhatistheminimumamountoficeneeded�42%tocoolitto0°C?WoulditbebettertoletTheheatlossistheteacooltoroomtemperaturebefore5300J�2200J�2900Jaddingtheice?Heatlostbythetea68.StampingPressAmetalstampingmachineQ�mC�Tinafactorydoes2100Jofworkeachtimeitstampsoutapieceofmetal.Eachstamped�(1.0kg)(4180J/kg�K)(90°C)pieceisthendippedina32.0-kgvatofwater�376kJforcooling.ByhowmanydegreesdoestheAmountoficemeltedvatheatupeachtimeapieceofstampedQmetalisdippedintoit?m��HfIfweassumethe2100Jofworkfrom376kJthemachineisabsorbedasthermal���1.1kg334kJenergyinthestampedpiece,thentheThus,youneedslightlymoreicethanvatmustabsorb2100Jintheformoftea,butthisratiowouldmakewateryheatfromeachpiece.Noworkisdonetea.Lettheteacooltoroomtempera-onthewater,onlyheatistransferred.turebeforeaddingtheice.ThechangeintemperatureofthewaterCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.isgivenbyLevel2�U�mC�T,71.Ablockofcopperat100.0°Ccomesincon-�Utactwithablockofaluminumat20.0°C,astherefore�T���mCshowninFigure12-21.Thefinaltempera-2100Jtureoftheblocksis60.0°C.Whatarethe����(32.0kg)(4180J/kg�°C)relativemassesoftheblocks?�0.016°C.69.A1500-kgautomobilecomestoastop100.0°C20.0°Cfrom25m/s.Alloftheenergyoftheautomobileisdepositedinthebrakes.CopperAluminumAssumingthatthebrakesareabout45kgofaluminum,whatwouldbethechangeintemperatureofthebrakes?60.0°C60.0°CTheenergychangeinthecaris�KE�1�(1500kg)(25m/s)2�4.7�105J.�2CopperAluminumIfallofthisenergyistransferredasworktothebrakes,then■Figure12-21�U��KE�mC�T.282SolutionsManualPhysics:PrinciplesandProblems
286Chapter12continuedTheheatlostfromthecopperequalsTherefore,�6.6Jisaddedtotheice.theheatgainedbythealuminum.TheTheamountoficemeltedisgivenby�Tforthecopperis�40.0°CandtheKEaluminumheatsby�40.0°C.m��Hftherefore,6.6J���mcopperCcopper�maluminumCaluminum3.34�105J/kgmC�2.0�10�5kgcopperaluminumand�����mCaluminumcopperThinkingCritically897J/kg�K����2.3page338385J/kg�K74.AnalyzeandConcludeAcertainheatThecopperblockhas2.3timesasengineremoves50.0Jofthermalenergymuchmassasthealuminumblock.fromahotreservoirattemperatureTH�545Kandexpels40.0Jofheattoa72.A0.35-kgblockofcopperslidingonthecolderreservoirattemperatureTL�325K.floorhitsanidenticalblockmovingattheIntheprocess,italsotransfersentropyfromsamespeedfromtheoppositedirection.onereservoirtotheother.Thetwoblockscometoastoptogethera.Howdoestheoperationoftheengineafterthecollision.Theirtemperatureschangethetotalentropyofthereservoirs?increaseby0.20°Casaresultofthecolli-Astheengineoperates,itremovession.Whatwastheirvelocitybeforetheenergyfromthehotreservoir.collision?QHThechangeininternalenergyoftheTherefore,�SH��T�sothattheHblocksisentropyofthehotreservoir�U�mC�Tdecreases.�(0.70kg)(385J/kg�°C)(0.20°C)TheentropyofthecoldreservoirQ�54J�S��Lincreases.ThenetL�TLTherefore,54Jequalsthekineticincreaseinentropyofthereservoirsenergyoftheblocksbeforethetogetheris12collision.54J�(2)����mv2�ST��SL��SH54Jv������0.35kgQLQH������TT�12m/sLH40.0J50.0J�S�����Level3T�325K545K73.A2.2-kgblockoficeslidesacrossarough�0.0313J/Kfloor.Itsinitialvelocityis2.5m/sanditsb.Whatwouldbethetotalentropychangefinalvelocityis0.50m/s.HowmuchoftheinthereservoirsifTiceblockmeltedasaresultoftheworkL�205K?donebyfriction?40.0J50.0J�S������0.103J/KT�205K545KTheworkdonebyfrictionequalstheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thetotalentropychangeinthenegativeofthechangeinkineticenergyoftheblock,assumingnottoomuchofreservoirs,andintheuniverse,hastheblockmelted.increasedapproximatelybyafactorofthree.12��KE���(2.2kg)(0.50m/s)2�1�(2.2kg)(2.5m/s)2��6.6J2Physics:PrinciplesandProblemsSolutionsManual283
287Chapter12continued75.AnalyzeandConcludeDuringagame,WritinginPhysicsthemetabolismofbasketballplayersoftenpage338increasesbyasmuchas30.0W.Howmuch78.Ourunderstandingoftherelationshipperspirationmustaplayervaporizeperbetweenheatandenergywasinfluencedbyahourtodissipatethisextrathermalenergy?soldiernamedBenjaminThompson,CountTheamountofthermalenergytoRumford;andabrewernamedJamesPrescottbedissipatedin1.00hisJoule.BothreliedonexperimentalresultstoU�(30.0J/s)(3600s/h)�1.08�105J.developtheirideas.Investigatewhatexperi-Theamountofwaterthisenergy,mentstheydidandevaluatewhetherornottransmittedasheat,wouldvaporizeisitisfairthattheunitofenergyiscalledtheQJouleandnottheThompson.m��HVIn1799,heatwasthoughttobealiquid1.08�105Jthatflowedfromoneobjecttoanother.���2.26�106J/kgHowever,CountRumfordthoughtthatheatwascausedbythemotionofparti-�0.0478kgclesinthemetalcannon.Hedidnotdo76.AnalyzeandConcludeChemistsuseanyquantitativemeasurementsandhiscalorimeterstomeasuretheheatproducedideaswerenotwidelyaccepted.In1843,bychemicalreactions.Forinstance,aJoule,doingcarefulmeasurements,chemistdissolves1.0�1022moleculesofameasuredthechangeintemperaturepowderedsubstanceintoacalorimetercon-causedbyaddingheatordoingworktaining0.50kgofwater.Themoleculesonaquantityofwater.Heprovedthatbreakupandreleasetheirbindingenergytoheatisaflavorofenergyandthatener-thewater.Thewatertemperatureincreasesgyisconserved.Jouledeservestheby2.3°C.Whatisthebindingenergypercreditandtheeponymicunit.moleculeforthissubstance?79.WaterhasanunusuallylargespecificheatTheamountofenergyaddedtotheandlargeheatsoffusionandvaporization.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.waterisOurweatherandecosystemsdependupon�U�mC�Twaterinallthreestates.Howwouldour�(0.50kg)(4180J/kg�°C)(2.3°C)worldbedifferentifwater’sthermodynamicpropertieswerelikeothermaterials,suchas�4.8kJmethanol?Theenergypermoleculeistherefore,Thelargespecificheatandlargeheats��4.8kJ�4.8�10�19J/moleculeoffusionandvaporizationmeanthat1022moleculeswater,ice,andwatervaporcanstorealotofthermalenergywithoutchanging77.ApplyConceptsAlloftheenergyonEarththeirtemperaturestoomuch.Theimpli-comesfromtheSun.Thesurfacetempera-4K.cationsaremany.TheoceansandlargetureoftheSunisapproximately10lakesmoderatethetemperatureWhatwouldbetheeffectonourworldif3K?changesinnearbyregionsonadailytheSun’ssurfacetemperaturewere10andseasonalbasis.Theday-to-nightStudentanswerswillvary.Answerstemperaturevariationnearalakeisshouldreflectchangingaveragemuchsmallerthantheday-to-nighttemperatureonEarth,differentweathertemperaturevariationinthedesert.Thepatterns,plantandanimalspecieslargeheatoffusionofwatercontrolsdyingout,etc.thechangeofseasonsinthefarnorthandsouth.Theabsorptionofenergybyfreezingwaterinthefallanditsrelease284SolutionsManualPhysics:PrinciplesandProblems
288Chapter12continuedinthespringslowsthetemperature81.Aweightlifterraisesa180-kgbarbelltoachangesintheatmosphere.Waterheightof1.95m.Howmuchworkisdoneabsorbsandstoresalotofenergyasitbytheweightlifterinliftingthebarbell?vaporizes.Thisenergycanbeusedto(Chapter10)drivemeteorologicalevents,suchasW�mghthunderstormsandhurricanes.�(180kg)(9.80m/s2)(1.95m)CumulativeReview�3.4�103Jpage33880.Aropeiswoundaroundadrumwitha82.InaGreekmyth,themanSisyphusisradiusof0.250mandamomentofinertiacondemnedbythegodstoforeverrollanof2.25kgm2.Theropeisconnectedtoaenormousrockupahill.Eachtimehe4.00-kgblock.(Chapter8)reachesthetop,therockrollsbackdowna.Findthelinearaccelerationoftheblock.tothebottom.Iftherockhasamassof215kg,thehillis33minheight,andSolveNewton’ssecondlawfortheSisyphuscanproduceanaveragepowerblock:mg�FT�ma,wherethepos-of0.2kW,howmanytimesin1hcanitivedirectionisdownwardandherolltherockupthehill?(Chapter11)whereFTistheforceoftheropeonthedrum.Newton’ssecondlawforTheamountofworkneededtorollthethedrumisFrockuponceisTr�I�orFTr�Ia/r.Thatis,F2.Therefore,W�mgh�(215kg)(9.80m/s2)(33m)T�Ia/rmg�(I/r2)a�ma.Thatis,�70,000Ja�mg/(m�I/r2)�g/10.0InonehourSisyphusdoesanamount�0.980m/s2.ofworkb.Findtheangularaccelerationofthe�(0.2�103J)(3600s)�720,000Jdrum.Hepushestherockupthehill2(720,000)/(70,000)�10timesinonehoura0.980m/s�������r0.250m�3.92rad/s2ChallengeProblemc.Findthetension,FT,intherope.page329I�Entropyhassomeinterestingproperties.F��T�rComparethefollowingsituations.Explainhow(2.25kgm2)(3.92rad/s2)andwhythesechangesinentropyaredifferent.����0.250m�35.3Nd.FindtheangularvelocityofthedrumQaftertheblockhasfallen5.00m.1kg1kgx�1�at2,sot��2x�����3.19s2aTiTfTherefore,���t�(3.92rad/s2)(3.19s)1.Heating1.0kgofwaterfrom273Kto274K.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�12.5rad/s�S��Q���mC��TTT(1.0kg)(4180J/kg�K)(274K�273K)������273K�15J/KPhysics:PrinciplesandProblemsSolutionsManual285
289Chapter12continued2.Heating1.0kgofwaterfrom353Kto354K.QmC�T�S������TT(1.0kg)(4180J/kg�K)(354K�353K)������353K�12J/K3.Completelymelting1.0kgoficeat273K.QmHf�S������TT(1.0kg)(3.34�105J/kg)����273K�1.2�103J/K4.Heating1.0kgofleadfrom273Kto274K.QmC�T�S������TT(1.0kg)(130J/kg�K)(274K�273K)������273K�0.48J/KCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.286SolutionsManualPhysics:PrinciplesandProblems
290CHAPTER13StatesofMatter4.Inatornado,thepressurecanbe15percentPracticeProblemsbelownormalatmosphericpressure.13.1PropertiesofFluidsSupposethatatornadooccurredoutsideapages341–348doorthatis195cmhighand91cmwide.Whatnetforcewouldbeexertedonthepage344doorbyasudden15percentdropin1.Theatmosphericpressureatsealevelis5Pa.Whatistheforceatseanormalatmosphericpressure?Inwhatabout1.0�10directionwouldtheforcebeexerted?levelthatairexertsonthetopofadeskthatis152cmlongand76cmwide?ThepressuredifferenceacrossthedoorisF�PA�Plw�(1.0�105Pa)(1.52m)(0.76m)Pdiff�(15%)(Patm)�1.2�105N�(0.15)(1.0�105Pa)�1.5�104PaF�PdiffA�Pdifflw2.Acartiremakescontactwiththegroundonarectangularareaof12cmby18cm.Ifthe�(1.5�104Pa)(1.95m)(0.91m)car’smassis925kg,whatpressuredoesthe�2.7�104Ndirectedfromtheinsidecarexertonthegroundasitrestsonallofthehouseoutwardfourtires?FFg,carmcarg5.Inindustrialbuildings,largepiecesofequip-P�������AA4lwmentmustbeplacedonwidesteelplates2)thatspreadtheweightoftheequipmentover(925kg)(9.80m/s����largerareas.Ifanengineerplanstoinstalla(4)(0.12m)(0.18m)454-kgdeviceonafloorthatisratedto�1.0�102kPa4Pa,withstandadditionalpressureof5.0�10howlargeshouldthesteelsupportplatebe?3.Aleadbrick,5.0cm�10.0cm�20.0cm,restsonthegroundonitssmallestface.FgmgThemaximumpressureP����Leadhasadensityof11.8g/cm3.WhatAApressuredoesthebrickexertontheground?mgTherefore,A��Pmbrick��V��lwh(454kg)(9.80m/s2)�(11.8g/cm3)(5.0cm)����4Pa5.0�10(10.0cm)(20.0cm)�8.9�10�2m2�1.18�104g�11.8kg6.AtankofheliumgasusedtoinflatetoyFg,brickmbrickg6PaP����balloonsisatapressureof15.5�10Alwandatemperatureof293K.Thetank’s�Vg�lwhgvolumeis0.020m3.Howlargeaballoon������hglwlwwoulditfillat1.00atmosphereand323K?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(11.8g/cm3)(20.0cm)PPT�1�V1��2�V2,soV�2P�1V12)1kg(100cm)2T1T22�P2T1(9.80m/s���1000g����2(1m)1.00atm�1.013�105Pa�23kPaPhysics:PrinciplesandProblemsSolutionsManual287
291Chapter13continued(323K)(15.5�106Pa)(0.020m3)V����SectionReview2�(1.013�105Pa)(293K)313.1PropertiesofFluids�3.4mpages341–3487.Whatisthemassoftheheliumgasinthepage348previousproblem?Themolarmassof10.PressureandForceSupposethatyouhaveheliumgasis4.00g/mol.twoboxes.Oneis20cm�20cm�20cm.PV�nRTTheotheris20cm�20cm�40cm.PV(15.5�106Pa)(0.020m3)a.Howdoesthepressureoftheaironthen�������RT(8.31Pa�m3/mol�K)(293K)outsideofthetwoboxescompare?�127.3molThepressureoftheairisthesameonthetwoboxes.m�(127.3mol)(4.00g/mol)�5.1�102gb.Howdoesthemagnitudeofthetotal8.Atankcontaining200.0Lofhydrogengasforceoftheaironthetwoboxesat0.0°Ciskeptat156kPa.Thetempera-compare?tureisraisedto95°C,andthevolumeisBecauseF�PAthetotalforceofdecreasedto175L.Whatisthenewtheairisgreaterontheboxwiththepressureofthegas?greaterarea.ThesecondboxhasPPtwicethesurfacearea,soithas�1V12V2T��TwithT1�273Kandtwicethetotalforceofthefirstbox.12T2�95°C�273°C�368K11.MeteorologyAweatherballoonusedbyTmeteorologistsismadeofaflexiblebagthat�2P1V1P2�Vallowsthegasinsidetofreelyexpand.Ifa2T1weatherballooncontaining25.0m3of(368K)(156kPa)(200.0L)����heliumgasisreleasedfromsealevel,what(175L)(273K)isthevolumeofgaswhentheballoon�2.4�102kPareachesaheightof2100m,wheretheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pressureis0.82�105Pa?Assumethat9.Theaveragemolarmassofthecomponentsthetemperatureisunchanged.ofair(mainlydiatomicoxygengasandP1V1�P2V2diatomicnitrogengas)isabout29g/mol.Whatisthevolumeof1.0kgofairatP1V1V�2�Patmosphericpressureand20.0°C?2PV�nRT(1.013�105Pa)(25.0m3)����0.82�105PanRTV��P�3.1�101m3m1.0�103gwheren������M29g/mol12.GasCompressionInacertaininternal-combustionengine,0.0021m3ofairatandT�20.0°C�273�293Katmosphericpressureand303Kisrapidly1.0�103g����(8.31Pa�m3/mol�K)(293K)compressedtoapressureof20.1�105Pa29g/molV����5Pa)andavolumeof0.0003m3.Whatisthe(1.013�10finaltemperatureofthecompressedgas?�0.83m3PP�1V1��2V2TT12TT�1P2V22�P1V1288SolutionsManualPhysics:PrinciplesandProblems
292Chapter13continued(303K)(20.1�105Pa)(0.0003m3)Thereareanequalnumberofparticles�����(1.013�105Pa)(0.0021m3)inthetwosamples.Inanidealgas,thesizeoftheparticlesisnotrelevantto�9�102Kthevolumeofthegasorthepressureexertedbythegas.13.DensityandTemperatureStartingat0°C,howwillthedensityofwaterchangeifitisheatedto4°C?To8°C?SectionReviewAsthewaterisheatedfrom0°C,thedensitywillincreaseuntilitreachesa13.2ForcesWithinLiquidsmaximumat4°C.Onfurtherheatingtopages349–3518°C,thedensityofthewaterwillpage351decrease.17.EvaporationandCoolingInthepast,whenababyhadahighfever,thedoctor14.TheStandardMolarVolumeWhatisthemighthavesuggestedgentlyspongingoffvolumeof1.00molofagasatatmosphericthebabywithrubbingalcohol.Whywouldpressureandatemperatureof273K?thishelp?nRTSincealcoholevaporateseasily,thereisV���Paverynoticeableevaporativecooling(1.00mol)(8.31Pa�m3/mol�K)(273K)effect.������1.013�105Pa�0.0224m318.SurfaceTensionApaperclip,whichhasadensitygreaterthanthatofwater,canbe15.TheAirinaRefrigeratorHowmanymadetostayonthesurfaceofwater.Whatmolesofairareinarefrigeratorwithavol-proceduresmustyoufollowforthistoumeof0.635m3atatemperatureofhappen?Explain.2.00°C?IftheaveragemolarmassofairisThepaperclipshouldbeplacedcare-29g/mol,whatisthemassoftheairinthefullyandflatlyontothesurfaceoftherefrigerator?water.ThiswillreducetheweightperPVunitareaofwatersurfaceonwhichitn��RTwillrest.Thesurfacetensionofthe(1.013�105Pa)(0.635m3)waterthenissufficienttosupportthe�����(8.31Pa�m3�mol�K)(275K)reducedweightperunitareaofthepaperclip.�28.1molm�nM19.LanguageandPhysicsTheEnglishlan-guageincludesthetermsadhesivetapeand�(28.1mol)(29g/mol)workingasacohesivegroup.Intheseterms,�0.81kgareadhesiveandcohesivebeingusedinthesamecontextastheirmeaningsinphysics?16.CriticalThinkingComparedtotheparti-Yes,adhesivetapeisstickingtosome-clesthatmakeupcarbondioxidegas,thethingdifferentthantape.Acohesiveparticlesthatmakeupheliumgasareverygroupisacollectionofpeopleworkingsmall.Whatcanyouconcludeaboutthetogether.numberofparticlesina2.0-LsampleofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.carbondioxidegascomparedtothenum-20.AdhesionandCohesionIntermsofberofparticlesina2.0-Lsampleofheliumadhesionandcohesion,explainwhygasifbothsamplesareatthesametemper-alcoholclingstothesurfaceofaglassrodatureandpressure?butmercurydoesnot.Physics:PrinciplesandProblemsSolutionsManual289
293Chapter13continuedAdhesionistheforcebetweenunlikeF(1600N)(72cm2)F�1A2���materials.Alcoholhasagreater2��A1440cm21adhesiveattractiontoglassthanmer-1N�8.0�10curyhas.Thecohesiveforcesofmer-curyarestrongenoughtoovercomeits24.Amechanicexertsaforceof55Nonaadhesiveforcewithglass.0.015m2hydraulicpistontoliftasmallautomobile.Thepistonthattheautomobile21.FloatingHowcanyoutellthatthepaper2.Whatisthesitsonhasanareaof2.4mclipinproblem18wasnotfloating?weightoftheautomobile?Ifthepaperclipbrokethroughthesur-F(55N)(2.4m2)faceofthewater,itsank.AnobjectthatF�1A2��3N2��A(0.015m2)�8.8�10floatswouldsimplybobbacktothe1surface.25.Bymultiplyingaforce,ahydraulicsystem22.CriticalThinkingOnahot,humidday,servesthesamepurposeasaleverorBethsatonthepatiowithaglassofcoldseesaw.Ifa400-Nchildstandingononewater.Theoutsideoftheglasswascoatedpistonisbalancedbya1100-Nadultwithwater.Heryoungersister,Jo,suggestedstandingonanotherpiston,whatisthethatthewaterhadleakedthroughtheglassratiooftheareasoftheirpistons?fromtheinsidetotheoutside.SuggestanF�1A2FexperimentthatBethcoulddotoshowJo2�A1wherethewatercamefrom.A2F2400NBethcouldweightheglassbefore������0.4A1F11100NputtingitintherefrigeratorforawhileTheadultstandsonthelargerpiston.tocoolitdown.Thenshecouldremoveitfromtherefrigeratorandallowmois-26.Inamachineshop,ahydraulicliftisusedturetocollectontheoutside.Finally,toraiseheavyequipmentforrepairs.Theshewouldweightheglassasecondsystemhasasmallpistonwithacross-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.time.Ifwatersimplyleaksfromthesectionalareaof7.0�10�2m2andalargeinsidetotheoutside,themassofthepistonwithacross-sectionalareaofglassandwaterwillbeunchanged.2.1�10�1m2.AnengineweighingHowever,ifthemoistureiscondensa-2.7�103Nrestsonthelargepiston.tion,therewillbeanincreaseinthemassatthesecondweighing.a.Whatforcemustbeappliedtothesmallpistontolifttheengine?F�1A2FPracticeProblems2�A113.3FluidsatRestand(2.7�103N)(7.0�10�2m2)�����2.1�10�1m2inMotionpages352–358�9.0�102Nb.Iftheenginerises0.20m,howfardoespage353thesmallerpistonmove?23.Dentists’chairsareexamplesofhydraulic-liftsystems.Ifachairweighs1600NandV1�V2andA1h1�A2h2restsonapistonwithacross-sectionalareaA1h1(2.1�10�1m2)(0.20m)of1440cm2,whatforcemustbeappliedtoh2�������2m2A27.0�10thesmallerpiston,withacross-sectionalareaof72cm2,toliftthechair?�0.60m290SolutionsManualPhysics:PrinciplesandProblems
294Chapter13continuedpage356waterandisbarelysubmerged,leavingthe27.Commonbrickisabout1.8timesdenserbricksdry?thanwater.WhatistheapparentweightofThefoamwoulddisplacea0.20m3blockofbricksunderwater?3V�(1.0m)(1.0m)(0.10m)�0.10mFofwater.Theweightofthefoamisapparent�Fg�Fbuoyant��brickVg��waterVgFg,foam��foamVg�(��(1.0�102kg/m3)(0.10m3)brick��water)Vg(9.80m/s2)�(1.8�103kg/m3��98N1.00�103kg/m3)Thebuoyantforceis(0.20m3)(9.80m/s2)Fbuoyant��waterVg�1.6�103N�(1.00�103kg/m3)(0.10m3)(9.80m/s2)28.Agirlisfloatinginafreshwaterlakewith�980Nherheadjustabovethewater.Ifsheweighs610N,whatisthevolumeofthesubmergedTheweightofbrickthatyoucouldstackpartofherbody?isSheisfloatingsoshedisplacesaFg,brick�Fbuoyant�Fgfoamvolumeofwaterthatweighsasmuch�980N�98Nasshedoes.2N�8.8�10Fg�Fbuoyant��waterVgF31.CanoesoftenhaveplasticfoamblocksgV��mountedundertheseatsforflotationin�watergcasethecanoefillswithwater.Whatisthe610Napproximateminimumvolumeoffoam�����(1.00�103kg/m3)(9.80m/s2)neededforflotationfora480-Ncanoe?�6.2�10�2m3Thebuoyantforceonthefoammustequal480N.Weareassumingthe29.Whatisthetensioninawiresupportingacanoeismadeofdensematerial.1250-Ncamerasubmergedinwater?TheFvolumeofthecamerais16.5�10�3m3.buoyant��waterVgFToholdthecamerainplacethetensionbuoyantV���inthewiremustequaltheapparentwatergweightofthecamera.480N�����(1.00�103kg/m3)(9.80m/s2)T�Fapparent�F�4.9�10�2m3g�Fbuoyant�Fg��waterVg�1250N�(1.00�103kg/m3)SectionReview(16.5�10�3m3)(9.80m/s2)13.3FluidsatRestandCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.09�103NinMotionpages352–35830.Plasticfoamisabout0.10timesasdensepage358aswater.Whatweightofbrickscouldyou32.FloatingandSinkingDoesafullsodapopstackona1.0m�1.0m�0.10mslabcanfloatorsinkinwater?Tryit.Doesitmat-offoamsothattheslaboffoamfloatsinterwhetherornotthedrinkisdiet?AllsodaPhysics:PrinciplesandProblemsSolutionsManual291
295Chapter13continuedpopcanscontainthesamevolumeofliquid,354mL,anddisplacethesamevol-umeofwater.Whatisthedifferencebetweenacanthatsinksandonethatfloats?Thedifferenceisalotofsugar.Aboutone-fourthcupofsugarisdissolvedintheregulardrink,makingitdenserthanwater.Thedietdrinkhasasmallamountofanartificialsweetener.Thedietdrinkislessdensethanthesugar-ladenregularsoftdrink.33.FloatingandDensityAfishingbobbermadeofcorkfloatswithone-tenthofitsvolumebelowthewater’ssurface.Whatisthedensityofcork?Theweightofthewaterdisplacedequalstheweightofthebobber.Fg��waterVwaterg��corkVcorkg�VTherefore,co�rk��w�ater��Vwatercork1���10Thecorkisaboutone-tenthasdenseaswater.34.FloatinginAirAheliumballoonrisesbecauseofthebuoyantforceoftheairliftingit.Thedensityofheliumis0.18kg/m3,andthedensityofairis1.3kg/m3.Howlargeavolumewouldaheliumballoonneedtolifta10-Nleadbrick?Fapparentmustequal�10Ntocounteracttheweightoftheleadbrick.Fapparent�Fg�Fbuoyant��heliumVballoong��airVballoong�(�helium��air)VballoongCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thus,FapparentV��balloon�(�helium��air)g�10N������(0.18kg/m3�1.3kg�m3)(9.80m�s2)�0.9m335.TransmissionofPressureAtoyrocketlauncherisdesignedsothatachildstompsonarubbercylinder,whichincreasestheairpressureinalaunchingtubeandpushesafoamrocketintothesky.Ifthechildstompswithaforceof150Nona2.5�10�3m2areapiston,whatistheadditionalforcetransmittedtothe4.0�10�4m2launchtube?F1A2F�2�A1(150N)(4.0�10�4m2)����2.5�10�3m2�24N292SolutionsManualPhysics:PrinciplesandProblems
296Chapter13continued36.PressureandForceAnautomobileweigh-Thefast-movingairofthetornadohasaing2.3�104Nisliftedbyahydrauliccylin-lowerpressurethanthestillairinsidederwithanareaof0.15m2.thehouse.Therefore,theairinsidethea.Whatisthepressureinthehydraulichouseisatahigherpressureandpro-cylinder?ducesanenormousforceonthewin-dows,doors,andwallsofthehouse.FP���ThispressuredifferenceisreducedbyAopeningdoorsandwindowstoletthe2.3�104N���airflowfreelytotheoutside.0.15m2�1.5�105Pab.ThepressureintheliftingcylinderisPracticeProblemsproducedbypushingona0.0082m213.4Solidscylinder.Whatforcemustbeexertedonpages359–363thissmallcylindertolifttheautomobile?page362F1A239.Apieceofaluminumhousesidingis3.66mF�2�A1longonacoldwinterdayof�28°C.How(2.3�104N)(0.0082m2)muchlongerisitonaveryhotsummerday����2at39°C?0.15m�1.3�103NL2�L1��L1(T2�T1),soL��L1(T2�T1)37.DisplacementWhichofthefollowing�(25�10�6°C�1)(3.66m)displacesmorewaterwhenitisplacedin(39°C�(�28°C))anaquarium?�6.1�10�3m�6.1mma.A1.0-kgblockofaluminumora1.0-kgblockoflead?40.Apieceofsteelis11.5cmlongat22°C.ItisBothaluminumandironwillsinktoheatedto1221°C,closetoitsmeltingtem-thebottomoftheaquarium.Becauseperature.Howlongisit?aluminumislessdensethaniron,L1kgofaluminumhasagreatervol-2�L1��L1(T2�T1)umethan1kgofiron.Therefore,the�(0.115m)�(12�10�6°C�1)blockofaluminumwilldisplace(0.115m)(1221°C�22°C)morewater.�1.2�10�1m�12cmb.A10-cm3blockofaluminumora10-cm3blockoflead?41.A400-mLglassbeakeratroomtemperatureisfilledtothebrimwithcoldwaterat4.4°C.Bothblockswillsink,andeachwillWhenthewaterwarmsupto30.0°C,howdisplacethesamevolumeofwater,10cm3.muchwaterwillspillfromthebeaker?Atthebeginning,400mLof4.4°Cwater38.CriticalThinkingAsyoudiscoveredinisinthebeaker.FindthechangeinPracticeProblem4,atornadopassingoveravolumeat30.0°C.housesometimesmakesthehouseexplodeV��VTCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.fromtheinsideout.HowmightBernoulli’s�(210�10�6°C�1)(400�10�6m3)principleexplainthisphenomenon?What(30.0°C�4.4°C)couldbedonetoreducethedangerofadoororwindowexplodingoutward?�2�10�6m3�2mLPhysics:PrinciplesandProblemsSolutionsManual293
297Chapter13continued42.Atanktrucktakesonaloadof45,725LofBywhatpercentagewouldtherulerbegasolineinHouston,wherethetemperatureincorrectat�30.0°C?is28.0°C.ThetruckdeliversitsloadinBecausethesteelshrinks,thedistancesMinneapolis,wherethetemperatureisbetweenthemillimetermarksdecrease�12.0°C.whencooled.a.HowmanylitersofgasolinedoestheLtruckdeliver?%incorrect�(100)����LVV2�V1�(100)�(Tf�Ti)������V1TV1T�6°C�1)�(100)(12�10V2��V1T�V1(�30.0°C�30.0°C)�(950�10�6°C�1)(45,725L)��0.072%(�12.0°C�28.0°C)�45,725L�4.4�104Lb.Whathappenedtothegasoline?SectionReviewThegasolinevolumedecreased13.4Solidsbecausethetemperaturedecreased.pages359–363Themassofthegasolineremainedpage363thesame.45.RelativeThermalContractionOnahotday,youareinstallinganaluminumscreen43.Aholewithadiameterof0.85cmisdrilleddoorinaconcretedoorframe.Youwantintoasteelplate.At30.0°C,theholeexactlythedoortofitwellonacoldwinterday.accommodatesanaluminumrodoftheShouldyoumakethedoorfittightlyinthesamediameter.Whatisthespacingbetweenframeorleaveextraroom?theplateandtherodwhentheyarecooledto0.0°C?Fitthedoortightly.AluminumshrinkswhencooledmuchmorethanconcreteThealuminumshrinksmorethanthedoes.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.steel.LetLbethediameteroftherod.Laluminum��LT46.StatesofMatterWhycouldcandlewaxbe�(25�10�6°C�1)consideredasolid?Whymightitalsobe(0.85cm)(0.0°C�30.0°C)consideredaviscousliquid?��6.38�10�4cmThewaxcouldbeconsideredasolidbecauseithasadefinitevolumeandForthesteel,thediameteroftheholeshape.ItcouldbeconsideredaviscousshrinksbyliquidbecausetheparticlesdonotformLsteel��LTafixedcrystallinepattern.�(12�10�6°C�1)(0.85cm)(0.0°C�30.0°C)47.ThermalExpansionCanyouheatapiece��3.06�10�4cmofcopperenoughtodoubleitslength?ThethermalexpansioncoefficientforThespacingbetweentherodandthecopperis16�10�6/°C.TodoubleitsholewillbelengthL�L��LT,whichmeansthat��1��(6.4�10�4cm�3.1�10�4cm)2�T�1�1.6�10�4cmT��1��44.Asteelrulerismarkedinmillimetersso1���thattherulerisabsolutelycorrectat30.0°C.16�10�6°C�1�63,000°C294SolutionsManualPhysics:PrinciplesandProblems
298Chapter13continuedThecopperwouldbevaporizedatthattemperature.StatesofMatter48.StatesofMatterDoesTable13-2provideawaytodistinguishbetweensolidsandliquids?fluidssolidsThecoefficientsofvolumeexpansionaremuchgreaterforliquidsthanforsolids.densityviscositydensityelasticity49.SolidsandLiquidsAsolidcanbedefinedasamaterialthatcanbebentandwillresistpressurebending.Explainhowthesepropertiesrelatetothebindingofatomsinasolid,MasteringConceptsbutdonotapplytoaliquid.page368Particlesinasolidarecloserand,there-52.Howareforceandpressuredifferent?(13.1)fore,moretightlybound.Theyvibrateaboutafixedposition.ThisallowstheForcedependsonlyonthepushorpullsolidtobebent,butitalsoresistsonanobject.Pressuredependsonthebending.Particlesinaliquidarefartherforceaswellastheareaoverwhichtheapartandlesstightlybound.Becauseforceisapplied.theparticlesarefreetoflowpastone53.Agasisplacedinasealedcontainer,andanother,aliquidcannotbebent.someliquidisplacedinacontainerofthe50.CriticalThinkingTheironringinsamesize.ThegasandliquidbothhaveFigure13-23wasmadebycuttingasmalldefinitevolume.Howdotheydiffer?(13.1)piecefromasolidring.IftheringintheTheliquid’svolumewillremainfigureisheated,willthegapbecomewiderunchanged.Thegaswillexpandtofillornarrower?Explainyouranswer.thevolumeofthecontainer.54.Inwhatwayaregasesandplasmassimilar?Inwhatwayaretheydifferent?(13.1)Bothgasesandplasmashavenodefi-nitevolumeandnodefiniteshape.Agasismadeofatoms.Aplasmaismadeofpositivelychargedionsandnegatively■Figure13-23chargedelectrons.TheparticlesofaThegapwillbecomewider.Alloftheplasmaaremoreenergeticthanthemeasurementsoftheringincreaseparticlesofagas.Plasmascanconductwhenheated.electricity.Gasescannot.55.TheSunismadeofplasma.HowisthisChapterAssessmentplasmadifferentfromtheplasmasonEarth?(13.1)ConceptMappingTheSun’splasmaisextremelyhot,butpage368moreimportantly,itisverydense—Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.51.CompletetheconceptmapbelowusingthedenserthanmostsolidsonEarth.followingterms:density,viscosity,elasticity,pressure.Atermmaybeusedmorethanonce.56.LakesAfrozenlakemeltsinthespring.Whateffectdoesthishaveonthetempera-tureoftheairabovethelake?(13.2)Physics:PrinciplesandProblemsSolutionsManual295
299Chapter13continuedTomelt,theicemustabsorbenergyin61.DoesArchimedes’principleapplytoantheamountofitsheatoffusionfromobjectinsideaflaskthatisinsideaspace-theairandwater.Itwillcooltheairshipinorbit?(13.3)aboveit.No,itdoesnot.Theapparentweightofthedisplacedfluidiszerobecausethe57.HikingCanteensusedbyhikersoftenarefluidisinfree-fall.Thus,thereisnocoveredwithcanvasbags.Ifyouwetthebuoyantforce.canvasbagcoveringacanteen,thewaterinthecanteenwillbecooled.Explain.(13.2)62.AstreamofwatergoesthroughagardenThewaterevaporatesintotheair,hoseintoanozzle.Asthewaterspeedsup,absorbingenergyfromthecanteenandwhathappenstothewaterpressure?(13.3)thewaterinside.ThewaterpressuredecreasesbecauseofBernoulli’sprinciple.58.WhatdotheequilibriumtubesinFigure13-24tellyouaboutthepressure63.Howdoesthearrangementofatomsinaexertedbyaliquid?(13.3)crystallinesubstancedifferfromthatinanamorphoussubstance?(13.4)Theatomsinacrystallinesubstancearearrangedinanorderedpattern.Intheamorphoussubstance,theatomsarerandomlyarranged.64.Doesthecoefficientoflinearexpansiondependontheunitoflengthused?Explain.(13.4)No.Thecoefficientisameasureoftheexpansionofanobjectrelativetoitstotallength.UnitsandtotallengthdoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.notchangethecoefficientoflinear■Figure13-24expansion.TheequilibriumtubesillustratethatpressureisindependentoftheshapeofApplyingConceptsthecontainer.page368–36965.Arectangularboxwithitslargestsurface59.AccordingtoPascal’sprinciple,whathap-restingonatableisrotatedsothatitspenstothepressureatthetopofacontainersmallestsurfaceisnowonthetable.Hasifthepressureatthebottomisincreased?thepressureonthetableincreased,(13.3)decreased,orremainedthesame?ChangesinpressurearedistributedThepressureincreased.Theweightequallytoallpartsofthecontainer.Thestayedthesame,buttheweightperpressureatthetopincreases.areaincreased.60.Howdoesthewaterpressure1mbelowthe66.Showthatapascalisequivalenttoasurfaceofasmallpondcomparewiththekg/m�s2.waterpressurethesamedistancebelowthePa�N/m2�(kg�m/s2)/m2surfaceofalake?(13.3)�kg/m�s2Sizeorshapeofthebodyofwaterdoesnotmatter,onlythedepth.Thepressureisthesameineachcase.296SolutionsManualPhysics:PrinciplesandProblems
300Chapter13continued67.ShippingCargoComparedtoanidenticalthefoil,willthesizeoftheholedecreaseoremptyship,wouldashipfilledwithtable-increase?Explain.tennisballssinkdeeperintothewaterorAsyouheatthefoil,theholebecomesriseinthewater?Explain.larger.HeatingtransfersmoreenergytoItwouldsinkdeeperintothewaterparticlesofthealuminum,causingthebecauseitwouldhaveagreaterweight.volumeofthealuminumtoincrease.68.Dropsofmercury,water,ethanol,and72.Equalvolumesofwaterareheatedintwoacetoneareplacedonasmooth,flatnarrowtubesthatareidentical,exceptthatsurface,asshowninFigure13-25.FromtubeAismadeofsoftglassandtubeBisthisfigure,whatcanyouconcludeaboutmadeofovenproofglass.Asthetemperaturethecohesiveforcesintheseliquids?increases,thewaterlevelriseshigherintubeBthanintubeA.Giveapossibleexplanation.Theovenproofglassexpandslessthanthesoftglasswhenheated.ThewaterdoesnotriseashighinAbecausethesoftglasstubeisexpandinginvolume.73.Aplatinumwireeasilycanbesealedinaglasstube,butacopperwiredoesnotformatightsealwiththeglass.Explain.Platinum’scoefficientofthermalexpan-■Figure13-25sionissimilartothatofglass,soitThecohesiveforcesarestrongestinexpandsandcontractsastheglassmercuryandweakestinacetone.Thedoes.Copperhasamuchlargercoeffi-strongerthecohesiveforce,themorecientthanglass.sphericalthedropwillbe.74.Fiveobjectswiththefollowingdensitiesare69.Howdeepwouldawatercontainerhavetoputintoatankofwater.betohavethesamepressureatthebottoma.0.85g/cm3d.1.15g/cm3asthatfoundatthebottomofa10.0-cmb.0.95g/cm3e.1.25g/cm3deepbeakerofmercury,whichis13.55c.1.05g/cm3timesasdenseaswater?Thedensityofwateris1.00g/cm3.ThediagraminFigure13-26showssixpossiblePwater�Pmercurypositionsoftheseobjects.Selectaposition,�waterhwaterg��mercuryhmercurygfrom1to6,foreachofthefiveobjects.Not�allpositionsneedtobeselected.mercuryh��water���waterhmercury�(13.55)(10.0cm)123�136cm4570.Alcoholevaporatesmorequicklythanwaterdoesatthesametemperature.WhatdoesthisobservationallowyoutoconcludeabouttheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.propertiesoftheparticlesinthetwoliquids?6Thecohesiveforcesofwateraregreaterthanthoseofalcohol.■Figure13-2671.SupposeyouuseaholepunchtomakeaThepositionsoftheobjectsshouldbecircularholeinaluminumfoil.Ifyouheata–1,b–2,c–6,d–6,e–6Physics:PrinciplesandProblemsSolutionsManual297
301Chapter13continuedMasteringProblemsdissolvedina2-Lbottleofsoda.ThemolarmassofCO13.1PropertiesofFluids2is44g/mol.a.Howmanymolesofcarbondioxidearepages369–370inthe2-Lbottle?(1L�0.001m3)Level1Fromtheidealgaslaw75.TextbooksA0.85-kgphysicsbookwithdimensionsof24.0cm�20.0cmisatrestPVn���onatable.RT(1.01�105Pa)(0.0080m3)a.Whatforcedoesthebookapplytothe�����(8.31Pa�m3�mol�K)(300.0K)table?�0.32molesTheforceonthetableistheweightofthebook.b.Whatisthemassofthecarbondioxide2)inthe2-Lbottleofsoda?W�mg�(0.85kg)(9.80m/sThemolecularweightofcarbon�8.3Ndioxideisb.Whatpressuredoesthebookapply?M�12�2(16)Thepressureappliedbythebookis�44g/molFP���Therefore,themassisAmgm�nM���lw�(0.32mol)(44g/mol)(0.85kg)(9.80m�s2)�14g�����(2.40�10�1m)(2.00�10�1m)2Pa79.AsshowninFigure13-27,aconstant-�1.7�10pressurethermometerismadewitha76.A75-kgsolidcylinderthatis2.5mlongcylindercontainingapistonthatcanmoveandhasanendradiusof7.0cmstandsonfreelyinsidethecylinder.Thepressureandoneend.Howmuchpressuredoesitexert?theamountofgasenclosedinthecylinderCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.arekeptconstant.AsthetemperatureFP���increasesordecreases,thepistonmovesupAordowninthecylinder.At0°C,theheightmg��2ofthepistonis20cm.Whatistheheightof�rthepistonat100°C?(75kg)(9.80m�s2)�����(0.070m)2Cylinder�4.8�104PaPiston20cm77.WhatisthetotaldownwardforceoftheGasatmosphereonthetopofyourheadrightnow?Assumethatthetopofyourheadhas2.■Figure13-27anareaofabout0.025mF�PA�(1.01�105Pa)(0.025m2)Becausethepressureiskeptconstant,V3N1/T1�V2/T2.Theheightofthepiston�2.5�10isdirectlyproportionaltothevolumeofthecylinder.Therefore,78.SoftDrinksSodasaremadefizzybythecarbondioxide(COh1h22)dissolvedinthe���liquid.AnamountofcarbondioxideequalT1T2toabout8.0Lofcarbondioxidegasatatmosphericpressureand300.0Kcanbe298SolutionsManualPhysics:PrinciplesandProblems
302Chapter13continuedhT(Onepoundpersquareinchequals12h2��T6.90�103Pa.)Thetermgaugepressure1meansthepressureaboveatmosphericpres-(20cm)(373K)���sure.Thus,theactualpressureinthetireis273K1.01�105Pa�(30.0psi)(6.90�103Pa/psi)�3�101cm�3.08�105Pa.Asthecarisdriven,thetire’stemperatureincreases,andthevolumeLevel2andpressureincrease.Supposeyoufilleda80.Apistonwithanareaof0.015m2enclosescar’stiretoavolumeof0.55m3atatem-aconstantamountofgasinacylinderwithperatureof280K.Theinitialpressurewasavolumeof0.23m3.Theinitialpressureof30.0psi,butduringthedrive,thetire’sthegasis1.5�105Pa.A150-kgmassistemperatureincreasedto310Kandthetire’svolumeincreasedto0.58m3.thenplacedonthepiston,andthepistonmovesdownwardtoanewposition,asa.Whatisthenewpressureinthetire?showninFigure13-28.IfthetemperaturePP�1�V1��2�V2isconstant,whatisthenewvolumeoftheTT12gasinthecylinder?PP�1V�1T2Volume�0.23m3Volume�?2�T1V2Pistonarea�0.015m2(3.08�105Pa)(0.55m3)(310K)�����(280K)(0.58m3)�3.2�105Pa150kgb.Whatisthenewgaugepressure?(30.0psi)(0.55m3)(310K)Pgauge����3)(280K)(0.58m�31psiGasGas13.3FluidsatRestandinMotionpage370Level1■Figure13-2882.ReservoirsAreservoirbehindadamisP1V1�P2V217-mdeep.Whatisthepressureofthewateratthefollowinglocations?P1V1V2��P�a.thebaseofthedam2P��hgP���1V1�(1.00�103kg/m3)(17m)mg�P1��A��(9.80m/s2)(1.5�105Pa)(0.23m3)�1.7�105Pa�(150kg)(9.80m/s2)b.4.0mfromthetopofthedam1.5�105Pa����0.015m2P��hgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.14m3�(1.00�103kg/m3)(4.0m)(9.80m/s2)Level3�3.9�104Pa81.AutomobilesAcertainautomobiletireisspecifiedtobeusedatagaugepressureof30.0psi,or30.0poundspersquareinch.Physics:PrinciplesandProblemsSolutionsManual299
303Chapter13continued83.Atesttubestandingverticallyinatest-tubeFg�195N�8N�203Nrackcontains2.5cmofoil(��0.81g/cm3)and6.5cmofwater.Whatisthepressureb.Therockisremovedfromtheaquarium,exertedbythetwoliquidsonthebottomofandtheamountofwaterisadjustedthetesttube?untilthescaleagainreads195N.Afishweighing2Nisaddedtotheaquarium.P�Poil�PwaterWhatisthescalereadingwiththefish��intheaquarium?oilhoilg��waterhwaterg�(810kg/m3)(0.025m)(9.80m/s2)�Fg�195N�2N�197N(1.00�103kg/m3)(0.065m)Ineachcasethebuoyantforceisequaltotheweightofthewater(9.80m/s2)displaced.�8.4�102Pa86.Whatisthesizeofthebuoyantforceona26.0-Nballthatisfloatinginfreshwater?84.AntiquesAnantiqueyellowmetalstatuetteofabirdissuspendedfromaspringscale.IftheballisfloatingThescalereads11.81NwhenthestatuetteFbuoyant�Fg�26.0Nissuspendedinair,anditreads11.19Nwhenthestatuetteiscompletelysubmerged87.Whatistheapparentweightofarocksub-inwater.mergedinwateriftherockweighs45Nina.Findthevolumeofthestatuette.airandhasavolumeof2.1�10�3m3?Fbuoyant��waterVg�Fg�FapparentFapparent�Fg�FbuoyantThus,�Fg��waterVgFg�Fapparent�45N�(1.00�103kg/m3)V����waterg(2.1�10�3m3)(9.80m/s2)11.81N�11.19N�����(1.00�103kg�m3)(9.80m�s2)�24NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�6.33�10�5m388.Whatisthemaximumweightthataballoonb.Isthebirdmadeofgoldfilledwith1.00m3ofheliumcanliftinair?(��19.3�103kg/m3)orgold-platedAssumethatthedensityofairis1.20kg/m3aluminum(��2.7�103kg/m3)?andthatofheliumis0.177kg/m3.Neglectthemassoftheballoon.m����VFapparent�Fg�FbuoyantFg��heliumVg��airVg��Vg�(�helium��air)Vg11.81N�����(6.33�10�5m3)(9.80m�s2)�(0.177kg/m3�1.20kg/m3)�19.0�103kg/m3(1.00m3)(9.80m/s2)Thestatuetteismadeofgold.��10.0N85.Duringanecologyexperiment,anaquariumLevel2half-filledwithwaterisplacedonascale.89.Ifarockweighs54NinairandhasanThescaleshowsaweightof195N.apparentweightof46Nwhensubmergeda.Arockweighing8Nisaddedtotheinaliquidwithadensitytwicethatofaquarium.Iftherocksinkstothebottomwater,whatwillbeitsapparentweightoftheaquarium,whatwillthescaleread?whenitissubmergedinwater?300SolutionsManualPhysics:PrinciplesandProblems
304Chapter13continuedFapparent,water�Fg��waterVgandFapparent,liquid�Fg�2�waterVgFg�Fapparent,liquidorV����2�watergSubstitutethisintothefirstequation.Fg�Fapparent,liquidF���apparent,water�Fg��waterg��2�waterg1�Fg���2��(Fg�Fapparent,liquid)1�����(Fg�Fapparent,liquid)21�����(54N�46N)2�5.0�101NLevel390.OceanographyAsshowninFigure13-29,alargebuoyusedtosupportanoceanographicresearchinstrumentismadeofacylindrical,?mhollowirontank.Thetankis2.1minheightand0.33mindiameter.Thetotalmassofthebuoyandtheresearchinstrumentisabout120kg.2.1mThebuoymustfloatsothatoneendisabovethewatertosupportaradiotransmitter.Assumingthatthemassofthebuoyisevenlydistributed,how0.33mmuchofthebuoywillbeabovethewaterlinewhenitisfloating?■Figure13-29TheheightofthebuoyabovewaterisVl1��wa�ter�above��Vltotalbuoym�����water����1�r2h�ltotalm��1����r2h��ltotalwater120kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1�����(2.1m)�����1��2(2.1m)(1.00�103kg�m3)�2(0.33m)��0.70mPhysics:PrinciplesandProblemsSolutionsManual301
305Chapter13continued13.4SolidsV��V1Tpages370–371�(36�10�6°C�1)(1.0m3)(45°C)Level191.Abarofanunknownmetalhasalengthof�1.6�10�3m30.975mat45°Candalengthof0.972mat23°C.Whatisitscoefficientoflinear96.BridgesBridgebuildersoftenuserivetsexpansion?thatarelargerthantherivetholetomakethejointtighter.TherivetiscooledbeforeitL2�L1����isputintothehole.SupposethatabuilderL1(T2�T1)drillsahole1.2230cmindiameterfora0.972m�0.975msteelrivet1.2250cmindiameter.Towhat����(0.975m)(23°C�45°C)temperaturemusttherivetbecooledifitis�1.4�10�4°C�1tofitintotherivethole,whichisat20.0°C?L2�L1��L1(T2�T1)92.Aninventorconstructsathermometerfrom(Lanaluminumbarthatis0.500minlengthT��2�L1)2�T1��Lat273K.Hemeasuresthetemperatureby1measuringthelengthofthealuminumbar.1.2230cm�1.2250cm�20.0°C����Iftheinventorwantstomeasurea1.0-K(12�10�6°C�1)(1.2250cm)changeintemperature,howpreciselymust��1.2�102°Chemeasurethelengthofthebar?T�1.0K�1.0°CLevel2L��L1T97.Asteeltankfilledwithmethanolis2.000m�(25�10�6°C�1)(0.500m)(1.0°C)indiameterand5.000minheight.Itis�1.3�10�5mcompletelyfilledat10.0°C.Ifthetempera-turerisesto40.0°C,howmuchmethanol(inliters)willflowoutofthetank,given93.BridgesHowmuchlongerwilla300-mthatboththetankandthemethanolwillCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.steelbridgebeona30°CdayinAugustexpand?thanona�10°CnightinJanuary?V��VL��L1T1T��L1(T2�T1)�6°C�1)(300m)�(�2h)(T�(12�10methanol��steel)(�r2�T1)(30°C�(�10°C))�(1200�10�6°C�1�35�10�6°C�1)�0.1m(�)(1.000m)2(5.000m)(40.0°C�10.0°C)94.Whatisthechangeinlengthofa2.00-m3�0.55mcopperpipeifitstemperatureisraisedfrom23°Cto978°C?98.Analuminumsphereisheatedfrom11°CtoL��L1T��L1(T2�T1)580°C.Ifthevolumeofthesphereis1.78cm3at11°C,whatistheincreaseinvolume�(16�10�6°C�1)(2.00m)ofthesphereat580°C?(978°C�23°C)V��V1T�3.1�10�2m�(75�10�6°C�1)(1.78cm3)95.Whatisthechangeinvolumeofa1.0-m3(580°C�11°C)concreteblockifitstemperatureisraised�7.6�10�2cm345°C?302SolutionsManualPhysics:PrinciplesandProblems
306Chapter13continued99.Thevolumeofacoppersphereis2.56cm3afterbeingheatedfrom12°Cto984°C.Whatwasthevolumeofthecoppersphereat12°C?V2�V1�V1�T�V1(1��T)V2V���11��T2.56cm3�����(1�(48�10�6°C�1)(984°C�12°C))�2.4cm3Level3100.Asquareofironplatethatis0.3300moneachsideisheatedfrom0°Cto95°C.a.Whatisthechangeinthelengthofthesidesofthesquare?L��L1T��L1(T2�T1)�(12�10�6°C�1)(0.3300m)(95°C�0°C)�3.8�10�4mb.Whatistherelativechangeinareaofthesquare?Arelativechange��A1A�A�2�1�A1L2�L2���21L21(L2�L2���1�L)1L21(0.3300m�3.8�10�4m)2�(0.3300m)2������(0.3300m)2�2.3�10�3101.Analuminumcubewithavolumeof0.350m3at350.0Kiscooledto270.0K.a.Whatisitsvolumeat270.0K?V2�V1�V1�T�V1(1��T)�V1(1��(T2�T1))�(0.350m3)(1�(75�10�6°C�1)(270.0K�350.0K))�0.348m3b.Whatisthelengthofasideofthecubeat270.0K?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1��3L�(V2)1���(0.348m3)3�0.703mPhysics:PrinciplesandProblemsSolutionsManual303
307Chapter13continued102.IndustryAmachinistbuildsarectangularmechanicalpartforaspecialrefrig-eratorsystemfromtworectangularpiecesofsteelandtworectangularpiecesofaluminum.At293K,thepartisaperfectsquare,butat170K,thepartbecomeswarped,asshowninFigure13-30.Whichpartsweremadeofsteelandwhichweremadeofaluminum?2211T�293K33T�170K44■Figure13-30Parts1and2experiencedagreaterreductioninlengththanparts3and4;therefore,parts1and2musthavebeenmadeofaluminum,whichhasalargercoefficientofexpansionthansteel.MixedReviewpage371Level1103.Whatisthepressureonthehullofasubmarineatadepthof65m?P�Patmosphere��watergh�(1.01�105Pa)�(1.00�10�3kg/m3)(9.80m/s2)(65m)�7.4�105Pa104.ScubaDivingAscubadiverswimmingatadepthof5.0munderwaterexhalesCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a4.2�10�6m3bubbleofair.Whatisthevolumeofthatbubblejustbeforeitreachesthesurfaceofthewater?P1V1�P2V2P1V1V�2�P2(Patmosphere��watergh)V1�����Patmosphere(1.01�105Pa�(1.00�103kg�m3)(9.80m�s2)(5.0m))(4.2�10�6m3)���������1.01�105Pa�6.2�10�6m3105.An18-Nbowlingballfloatswithabouthalfoftheballsubmerged.a.Whatisthediameterofthebowlingball?VballF�g��Vwaterg����2g,43�4d3�d3whereVball��3��r�3����2����6�1�d3ThenFg��2�����6g,304SolutionsManualPhysics:PrinciplesandProblems
308Chapter13continued312Fgsothatd������g3(12)(18N)����������(1.00�103kg�m3)(9.80m�s2)�0.19mb.Whatwouldbetheapproximateapparentweightofa36-Nbowlingball?Halftheballsankwhentheweightwas18N.Theapparentweightofthe36-Nballshouldbenearzero.Level2106.Analuminumbarisfloatinginabowlofmercury.Whenthetemperatureisincreased,doesthealuminumfloathigherorsinkdeeperintothemercury?Thevolumecoefficientofexpansionofmercuryisgreaterthanthevolumecoefficientofexpansionofaluminum.Therefore,astheyareheated,thealuminumbecomesdenserrelativetothemercuryandwouldsinkdeeperintothemercury.107.Thereis100.0mLofwaterinan800.0-mLsoft-glassbeakerat15.0°C.Howmuchwillthewaterlevelhavedroppedorrisenwhenthebottleandwaterareheatedto50.0°C?Thewaterexpands:V��VT�(210�10�6°C�1)(100.0mL)(35.0°C)�0.735mLThebottleexpands:V��VT�(27�10�6°C�1)(800.0mL)(35.0°C)�0.756mLThewaterlevelwillgodownslightly,butnotenoughtonotice.108.AutoMaintenanceAhydraulicjackusedtoliftcarsforrepairsiscalledathree-tonjack.Thelargepistonis22mmindiameter,andthesmalloneis6.3mmindiameter.Assumethataforceof3tonsis3.0�104N.a.Whatforcemustbeexertedonthesmallpistontolifta3-tonweight?F1A2F2��A1F2��1�r2�r21Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.d2�F�21��d214N)6.3mm2�(3.0�10���22mm�2.5�103NPhysics:PrinciplesandProblemsSolutionsManual305
309Chapter13continuedb.MostjacksusealevertoreducetheThepressureinthewaterisforceneededonthesmallpiston.If(8.7�107Pa)/(1.01�105Pa)�theresistancearmis3.0cm,howlong860timesgreaterthanstandardairmusttheeffortarmofanidealleverbepressure.Therefore,thedensityofairtoreducetheforceto100.0N?wouldbe860timesgreaterthantheFdensityoftheaironthesurfaceofrLr�FeLetheocean.FrLrL�e�FeThinkingCritically(2.5�103N)(3.0cm)page372����100.0N111.ApplyConceptsYouarewashingdishes�75cminthesink.Aservingbowlhasbeenfloat-inginthesink.Youfillthebowlwithwater109.BallooningAhot-airballooncontainsafromthesink,anditsinkstothebottom.fixedvolumeofgas.Whenthegasisheat-Didthewaterlevelinthesinkgoupored,itexpandsandpushessomegasoutatdownwhenthebowlwassubmerged?thelower,openend.Asaresult,themassWhenitwasfloating,thebowldis-ofthegasintheballoonisreduced.Whyplacedavolumeofwaterthatweighedwouldtheairinaballoonhavetobehot-asmuchasitdid.Whenitsank,itdis-tertoliftthesamenumberofpeopleaboveplacedavolumeofwaterthatweighedVail,Colorado,whichhasanaltitudeoflessthanthebowl,becausethebuoy-2400m,thanabovethetidewaterflatsofancyforceistheweightofthewaterVirginia,whichhaveanaltitudeof6m?displaced.Inthesecondcase,theAtmosphericpressureislowerathigh-bowldisplaceslesswaterandtheleveleraltitudes.Therefore,themassoftheinthesinkgoesdown.volumeoffluiddisplacedbyaballoonofthesamevolumeislessathigher112.ApplyConceptsPersonsconfinedtobedaltitudes.ToobtainthesamebuoyantarelesslikelytodevelopbedsoresiftheyCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.forceathigheraltitudes,aballoonuseawaterbedratherthananordinarymustexpelmoregas,requiringhighermattress.Explain.temperatures.Thesurfaceofthewaterbedconformsmorethanthesurfaceofamattressto110.TheLivingWorldSomeplantsandani-thecontoursofyourbody.One“sinks”malsareabletoliveinconditionsofmoreeasilyintoawaterbed.Becauseextremepressure.�HO�mattress,thebuoyantforcefrom2a.Whatisthepressureexertedbytheawaterbedisless.waterontheskinofafishorwormthatlivesnearthebottomofthe113.AnalyzeandConcludeOnemethodofPuertoRicoTrench,8600mbelowthemeasuringthepercentageofbodyfatissurfaceoftheAtlanticOcean?Usebasedonthefactthatfattytissueisless1030kg/m3forthedensityofseawater.densethanmuscletissue.Howcanaper-son’saveragedensitybeassessedwithaThepressureisscaleandaswimmingpool?Whatmea-P��ghsurementsdoesaphysicianneedtorecord�(1030kg/m3)(9.80m/s2)(8600m)tofindaperson’saveragepercentageof�8.7�107Pabodyfat?Thephysicianweighsthepersonnor-b.Whatwouldbethedensityofairatmallyandthenweighsthepersonthatpressure,relativetoitsdensitytotallysubmerged.Weighthastobeabovethesurfaceoftheocean?306SolutionsManualPhysics:PrinciplesandProblems
310Chapter13continuedaddedtotheweighingdevicebecausethedensityofahumanisnormal-lylessthanthedensityofwater.Thevolumeofwaterdisplacedbythepersonalsoshouldbemeasured.Theaveragedensityofthepersoncanbecalculatedfromthebalanceofforcesthatholdthepersoninequilibri-umunderwater.114.AnalyzeandConcludeAdownwardforceof700Nisrequiredtofullysubmergeaplasticfoamsphere,asshowninFigure13-31.Thedensityofthefoamis95kg/m3.a.Whatpercentageofthespherewouldbesubmergedifthespherewerereleasedtofloatfreely?Thedensityofthefoamrelativetothe95kg�m3wateris����0.095,so1.00�103kg�m39.5percentofthefloatingspherewouldbe700Nsubmerged.b.Whatistheweightofthesphereinair?■Figure13-31Theweightofwaterdisplacedby9.5percentofthesphere’svolumebalancestheentireweightofthesphere,Fg.Anadditional700Nisneededtosubmergetheremaining90.5percentofthesphere’svolume.Thus,Fg700N����0.0950.905F1Ng�7�10c.Whatisthevolumeofthesphere?Fbuoyant�Fg�Fdown�waterVg��foamVg�FdownFdownV���(�water��down)g700N������(1.00�103kg�m3�95kg�m3)(9.80m�s2)�8�10�2m3115.ApplyConceptsTropicalfishforaquariumsareoftentransportedhomefrompetshopsintransparentplasticbagsfilledmostlywithwater.Ifyouplacedafishinitsunopenedtransportbaginahomeaquarium,whichofthecasesinFigure13-32bestrepresentswhatwouldhappen?Explainyourreasoning.BagBagAquariumwaterwaterwaterlevelCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.levellevelBagwaterlevelAquariumAquariumwaterlevelwaterlevel■Figure13-32Physics:PrinciplesandProblemsSolutionsManual307
311Chapter13continuedThedensityofthewaterinthebag,theofoxygengas.Avogadrobuiltonfish,andtheplasticareallneartheGay-Lussac’sworktodevelopthedensityofthewaterintheaquarium.relationshipbetweenmolesofagasTherefore,thebagshouldfloatwithandvolume.thewaterlevelinthebagatthesameheightasthewaterlevelintheCumulativeReviewaquarium.page372118.TwoblocksareconnectedbyastringoverWritinginPhysicsafrictionless,masslesspulleysuchpage372thatoneisrestingonaninclinedplane116.Somesolidmaterialsexpandwhentheyandtheotherishangingoverthetopedgearecooled.Waterbetween4°and0°Cisoftheplane,asshowninFigure13-33.themostcommonexample,butrubberThehangingblockhasamassof3.0kgbandsalsoexpandinlengthwhencooled.andtheblockontheplanehasamassofResearchwhatcausesthisexpansion.2.0kg.ThecoefficientofkineticfrictionRubberbandsaremadeoflongrubberbetweentheblockandtheinclinedplanemoleculescalledpolymersthatactlikeis0.19.Answerthefollowingquestionschainswithmanylonglinks.Theprop-assumingtheblocksarereleasedfromrest.ertiesofrubbercomefromtheability(Chapter5)ofthechainlinkstotwistandturn.a.Whatistheaccelerationoftheblocks?Whentherubberiscolder,thepolymerlinksarestretchedoutinastraightline,likethelinksinasteelchainthatyouholdatoneendandlethang2.0kgfreely.Becausethelinksareordered3.0kgthatway,thepolymershaverelativelylittledisorder,orentropy.Addingheat45°tothepolymersincreasestheirther-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.malmotion.Thelinksbegintoshake■Figure13-33aboutandtheirdisorderincreases.IfForthe2-kgblock,youshakeachainlikethis,youwillT��seethatitsaveragelengthbecomeskFN�mgsin��malessthanifthechainwerehangingwhereFN�mgcos�isthenormalmotionless.force.Thus,117.ResearchJosephLouisGay-LussacandhisT��contributionstothegaslaws.Howdidkmgcos��mgsin��maGay-Lussac’sworkcontributetothediscov-T�(mg)(�kcos��sin�)�maeryoftheformulaforwater?Forthe3-kgblock,Gay-LussacwasaFrenchscientistMg�T�Mawhoalsowasinterestedinhigh-altitudeballoonascents.Hediscov-or,T�Mg�MaeredthatwhengasesareatthesameSubstitutethisforTinthe2-kgtemperatureandpressure,theirvol-blockequation.umesreactinratiosofsmall,wholeMg�Ma�(mg)(�kcos��sin�)numbers.Gay-Lussac’sworkcon-�matributedtothediscoveryofwater’sformulabyshowingthattwovolumesofhydrogengasreactwithonevolume308SolutionsManualPhysics:PrinciplesandProblems
312Chapter13continuedSolveforacceleration.Mg�(mg)(�a�����kcos��sin�)m�M(3.0kg)(9.80m�s2)�(2.0kg)(9.80m�s2)((0.19)(cos45°)�sin45°)���������2.0kg�3.0kg�2.6m/s2b.Whatisthetensioninthestringconnectingtheblocks?TofindT,usetheequationforthe3-kgblock.T�Mg�Ma�M(g�a)�(3.0kg)(9.80m/s2�2.6m/s2)�22N119.Acompactcarwithamassof875kg,movingsouthat15m/s,isstruckbyafull-sizedcarwithamassof1584kg,movingeastat12m/s.Thetwocarssticktogether,andmomentumisconserved.(Chapter9)a.Sketchthesituation,assigningcoordinateaxesandidentifying“before”and“after.”y-axisAmA�875kgBeforevA�15m/s(State1)BAfter(State2)x-axismB�1584kgv2�?vB�12m/sp2�?m2�2459kgb.Findthedirectionandspeedofthewreckimmediatelyafterthecollision,rememberingthatmomentumisavectorquantity.pA1�mAvA�(875kg)(15m/s)�1.31�104kg�m/ssouthpB1�mBvB�(1584kg)(12m/s)�1.90�104kg�m/seastp2���pA12��pB12��(1.31���104kg��m/s�)2�(1.90��1�04kg��m/s)�2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�2.3�104kg�m/sptan���B1pA1Physics:PrinciplesandProblemsSolutionsManual309
313Chapter13continuedp��tan�1���B1ChallengeProblempA1page363�11.90�104kg�m/s�tan�����1.31�104kg�m/sYouneedtomakea1.00-m-longbarthatexpandswithtemperatureinthesamewayasa�55°eastofsouth1.00-m-longbarofcopperwould.Asshowninp22.3�104kg�m/sthefigureattheright,yourbarmustbemadev���2��m2459kg2fromabarofironandabarofaluminum�9.4m/sattachedendtoend.Howlongshouldeachofthembe?c.ThewreckskidsalongthegroundandLcomestoastop.Thecoefficientofcopper�Laluminum�Lironkineticfrictionwhilethewreckisskid-anddingis0.55.Assumethattheaccelera-�copperLcopperT�tionisconstant.Howfardoesthe(�aluminumLaluminum��ironLiron)Twreckskidafterimpact?Tofindthedistance,usetheequa-SubstitutingLaluminum�tionofmotion:Lcopper�Liron,thisgivesv2�v2�2a(d�dii)(�copper��aluminum)LcopperwherethefinalvelocityiszeroandLiron������iron��aluminumdi�0.Solveford:(16�10�6°C�1�25�10�6°C�1)(1.00m)�v2������12�10�6°C�1�25�10�6°C�1d��i2a�0.69mTofindacceleration,noticethattheLaluminum�Lcopper�Lironforcethatslowsthecarsequalsthefrictionalforce.�1.00m�0.69m(m�0.31ma�mb)a���k(ma�mb)gCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a���kgThedistanceisthenv2d��02�kg(9.4m�s)2����(2)(0.55)(9.80m�s2)�8.2m120.A188-Wmotorwillliftaloadattherate(speed)of6.50cm/s.Howgreataloadcanthemotorliftatthisrate?(Chapter10)v�6.50cm/s�0.0650m/sWFddP�������F�����FvtttP�FgvP188W3NF������2.89�10g�v0.0650m/s310SolutionsManualPhysics:PrinciplesandProblems
314CHAPTER14VibrationsandWaves12PE��kxPracticeProblemssp�214.1PeriodicMotion2PEsp(2)(48J)x�����������0.61mpages375–380k256N/mpage3781.Howmuchforceisnecessarytostretchapage379spring0.25mwhenthespringconstant6.WhatistheperiodonEarthofapendulumis95N/m?withalengthof1.0m?F�kxT�2��l��2��1.0�m�2.0s��g��9.80m�/s2�(95N/m)(0.25m)�24N7.HowlongmustapendulumbeontheMoon,whereg�1.6m/s2,tohavea2.Aspringhasaspringconstantof56N/m.periodof2.0s?Howfarwillitstretchwhenablocklweighing18Nishungfromitsend?T�2�����gF�kx22T2)2.0sF18Nl�g�����(1.6m/s�����0.16m2�2�x�������0.32mk56N/m8.Onaplanetwithanunknownvalueofg,3.Whatisthespringconstantofaspringthattheperiodofa0.75-m-longpendulumstretches12cmwhenanobjectweighingis1.8s.Whatisgforthisplanet?24Nishungfromit?lF�kxT�2�����gF22k��g�l�2���(0.75m)�2���9.1m/s2x����T1.8s24N���0.12m�2.0�102N/mSectionReview14.1PeriodicMotion4.Aspringwithaspringconstantof144N/mpages375–380iscompressedbyadistanceof16.5cm.page380Howmuchelasticpotentialenergyisstored9.Hooke’sLawTwospringslookalikebutinthespring?havedifferentspringconstants.Howcould12PEsp��2�kxyoudeterminewhichonehasthegreaterspringconstant?�1�(144N/m)(0.165m)2�1.96J�2Hangthesameobjectfrombothsprings.TheonethatstretcheslessCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.5.Aspringhasaspringconstantof256N/m.hasthegreaterspringconstant.Howfarmustitbestretchedtogiveitanelasticpotentialenergyof48J?10.Hooke’sLawObjectsofvariousweightsarehungfromarubberbandthatissus-pendedfromahook.TheweightsoftheobjectsareplottedonagraphagainstthePhysics:PrinciplesandProblemsSolutionsManual311
315Chapter14continuedstretchoftherubberband.Howcanyou14.CriticalThinkingHowisuniformcirculartellfromthegraphwhetherornotthemotionsimilartosimpleharmonicrubberbandobeysHooke’slaw?motion?Howaretheydifferent?Ifthegraphisastraightline,therubberBothareperiodicmotions.InuniformbandobeysHooke’slaw.Ifthegraphiscircularmotion,theacceleratingforcecurved,itdoesnot.isnotproportionaltothedisplacement.Also,simpleharmonicmotionisone-11.PendulumHowmustthelengthofapen-dimensionalanduniformcirculardulumbechangedtodoubleitsperiod?motionistwo-dimensional.Howmustthelengthbechangedtohalvetheperiod?PracticeProblems12,soPE�sp�2kx14.2WavePropertiesPEx2pages381–386��1��1�PEx222page386(0.40m)215.Asoundwaveproducedbyaclockchimeis���(0.20m)2heard515maway1.50slater.�4.0a.Whatisthespeedofsoundoftheclock’schimeinair?Theenergyofthefirstspringis4.0timesgreaterthantheenergyofv��d�tthesecondspring.515m���12.EnergyofaSpringWhatisthedifference1.50sbetweentheenergystoredinaspringthatis�343m/sstretched0.40mandtheenergystoredinb.Thesoundwavehasafrequencyofthesamespringwhenitisstretched0.20m?436Hz.Whatistheperiodofthewave?lT2l21Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.T�2�����,so�������T���gTlf11Todoubletheperiod:1��436HzTll��2��2��2,so�2��4�3sT��ll�2.29�10111c.Whatisthewave’swavelength?Thelengthmustbequadrupled.vTohalvetheperiod:����fT2l21l21343m/s���������,so������T1l12l14436HzThelengthisreducedtoone-fourthits�0.787moriginallength.16.Ahikershoutstowardaverticalcliff465m13.ResonanceIfacar’swheelisoutofbal-away.Theechoisheard2.75slater.ance,thecarwillshakestronglyataspecifica.Whatisthespeedofsoundofthespeed,butnotwhenitismovingfasterorhiker’svoiceinair?slowerthanthatspeed.Explain.d(2)(465m)Atthatspeed,thetire’srotationv�������338m/st2.75sfrequencymatchestheresonantfrequencyofthecar.312SolutionsManualPhysics:PrinciplesandProblems
316Chapter14continuedb.Thewavelengthofthesoundis0.750m.SectionReviewWhatisitsfrequency?v338m/s14.2WavePropertiesv��f,sof�������451Hz�0.750mpages381–386c.Whatistheperiodofthewave?page386T�1���1��2.22�10�3s22.SpeedinDifferentMediaIfyoupullon�f451Hzoneendofacoiled-springtoy,doesthepulsereachtheotherendinstantaneously?17.IfyouwanttoincreasethewavelengthofWhathappensifyoupullonarope?Whatwavesinarope,shouldyoushakeitatahappensifyouhittheendofametalrod?higherorlowerfrequency?Compareandcontrastthepulsestravelingatalowerfrequency,becausewave-throughthesethreematerials.lengthvariesinverselywithfrequencyIttakestimeforthepulsetoreachtheotherendineachcase.Ittravelsfaster18.Whatisthespeedofaperiodicwavedistur-ontheropethanonthespring,andbancethathasafrequencyof3.50Hzandafastestinthemetalrod.wavelengthof0.700m?v��f�(0.700m)(3.50Hz)�2.45m/s23.WaveCharacteristicsYouarecreatingtransversewavesinaropebyshakingyour19.Thespeedofatransversewaveinastringishandfromsidetoside.Withoutchanging15.0m/s.Ifasourceproducesadisturbancethedistancethatyourhandmoves,youthathasafrequencyof6.00Hz,whatisitsbegintoshakeitfasterandfaster.Whatwavelength?happenstotheamplitude,wavelength,v15.0m/sfrequency,period,andvelocityofthewave?v��f,so��������2.50mf6.00HzTheamplitudeandvelocityremainunchanged,butthefrequencyincreases20.Fivepulsesaregeneratedevery0.100sinawhiletheperiodandthewavelengthtankofwater.Whatisthespeedofpropaga-decrease.tionofthewaveifthewavelengthofthesurfacewaveis1.20cm?24.WavesMovingEnergySupposethat�0.10�0s�0.0200s/pulse,soyouandyourlabpartnerareaskedto5pulsesdemonstratethatatransversewavetrans-T�0.0200sportsenergywithouttransferringmatter.��vT,soHowcouldyoudoit?�Tieapieceofyarnsomewherenearthev���Tmiddleofarope.Withyourpartner1.20cmholdingoneendoftherope,shakethe���0.0200sotherendupanddowntocreatea�60.0cm/s�0.600m/stransversewave.Notethatwhilethewavemovesdowntherope,theyarn21.Aperiodiclongitudinalwavethathasamovesupanddownbutstaysinthefrequencyof20.0Hztravelsalongacoilsameplaceontherope.spring.IfthedistancebetweensuccessiveCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.compressionsis0.600m,whatisthespeed25.LongitudinalWavesDescribelongitudinalofthewave?waves.Whattypesofmediatransmitv��f�(0.600m)(20.0Hz)�12.0m/slongitudinalwaves?Inlongitudinalwaves,theparticlesofthemediumvibrateinadirectionparalleltothemotionofthewave.Physics:PrinciplesandProblemsSolutionsManual313
317Chapter14continuedNearlyallmedia—solids,liquids,and30.CriticalThinkingAsanotherwaytogases—transmitlongitudinalwaves.understandwavereflection,covertheright-handsideofeachdrawinginFigure14-13a26.CriticalThinkingIfaraindropfallsintoawithapieceofpaper.Theedgeofthepaperpool,itcreateswaveswithsmallamplitudes.shouldbeatpointN,thenode.Now,con-Ifaswimmerjumpsintoapool,waveswithcentrateontheresultantwave,showninlargeamplitudesareproduced.Whydoesn’tdarkerblue.Notethatitactslikeawavetheheavyraininathunderstormproducereflectedfromaboundary.Istheboundaryalargewaves?rigidwall,orisitopen-ended?RepeatthisTheenergyoftheswimmeristrans-exerciseforFigure14-13b.ferredtothewaveinasmallspaceFigure14-14abehaveslikearigidwalloverashorttime,whereastheenergybecausethereflectedwaveisinverted;oftheraindropsisspreadoutin14-14bbehaveslikeanopenendareaandtime.becausetheboundaryisanantinodeandthereflectedwaveisnotinverted.SectionReview14.3WaveBehaviorChapterAssessmentpages387–391ConceptMappingpage391page39627.WavesatBoundariesWhichofthe31.Completetheconceptmapusingthefol-followingwavecharacteristicsremainlowingtermsandsymbols:amplitude,unchangedwhenawavecrossesaboundaryfrequency,v,�,T.intoadifferentmedium:frequency,ampli-tude,wavelength,velocity,and/ordirection?WavesFrequencyremainsunchanged.Ingeneral,amplitude,wavelength,andCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.velocitywillchangewhenawaveentersspeedamplitudeperiodfrequencywavelengthanewmedium.Directionmayormaynotchange,dependingontheoriginaldirectionofthewave.vATf�28.RefractionofWavesNoticeinFigure14-17ahowthewavechangesMasteringConceptsdirectionasitpassesfromonemediumtopage396another.Cantwo-dimensionalwavescross32.Whatisperiodicmotion?Givethreeexam-aboundarybetweentwomediawithoutplesofperiodicmotion.(14.1)changingdirection?Explain.PeriodicmotionismotionthatrepeatsYes,iftheystriketheboundarywhileinaregularcycle.Examplesincludetravelingnormaltoitssurface,oriftheyoscillationofaspring,swingofasimplehavethesamespeedinbothmedia.pendulum,anduniformcircularmotion.29.StandingWavesInastandingwaveona33.Whatisthedifferencebetweenfrequencystringfixedatbothends,howisthenumberandperiod?Howaretheyrelated?(14.1)ofnodesrelatedtothenumberofantinodes?FrequencyisthenumberofcyclesorThenumberofnodesisalwaysonerepetitionspersecond,andperiodisthegreaterthanthenumberofantinodes.timerequiredforonecycle.Frequencyistheinverseoftheperiod.314SolutionsManualPhysics:PrinciplesandProblems
318Chapter14continued34.Whatissimpleharmonicmotion?Givean41.Whatistheprimarydifferencebetweenaexampleofsimpleharmonicmotion.mechanicalwaveandanelectromagnetic(14.1)wave?(14.2)SimpleharmonicmotionisperiodicTheprimarydifferenceisthatmechani-motionthatresultswhentherestoringcalwavesrequireamediumtotravelforceonanobjectisdirectlypropor-throughandelectromagneticwavesdotionaltoitsdisplacement.Ablocknotneedamedium.bouncingontheendofaspringisoneexample.42.Whatarethedifferencesamongtransverse,longitudinal,andsurfacewaves?(14.2)35.IfaspringobeysHooke’slaw,howdoesitAtransversewavecausestheparticlesbehave?(14.1)ofthemediumtovibrateinadirectionThespringstretchesadistancethatisthatisperpendiculartothedirectionindirectlyproportionaltotheforcewhichthewaveismoving.Alongitudi-appliedtoit.nalwavecausestheparticlesofthemediumtovibrateinadirectionparallel36.Howcanthespringconstantofaspringbewiththedirectionofthewave.Surfacedeterminedfromagraphofforceversuswaveshavecharacteristicsofboth.displacement?(14.1)Thespringconstantistheslopeofthe43.WavesaresentalongaspringoffixedgraphofFversusx.length.(14.2)a.Canthespeedofthewavesinthespring37.Howcanthepotentialenergyinaspringbebechanged?Explain.determinedfromthegraphofforceversusSpeedofthewavesdependsonlydisplacement?(14.1)onthemediumandcannotbeThepotentialenergyistheareaunderchanged.thecurveofthegraphofFversusx.b.Canthefrequencyofawaveinthespringbechanged?Explain.38.DoestheperiodofapendulumdependonFrequencycanbechangedbythemassofthebob?Thelengthofthechangingthefrequencyatwhichthestring?Uponwhatelsedoestheperiodwavesaregenerated.depend?(14.1)no;yes;theaccelerationofgravity,g44.Whatisthewavelengthofawave?(14.2)Wavelengthisthedistancebetweentwo39.Whatconditionsarenecessaryforadjacentpointsonawavethatareinresonancetooccur?(14.1)phase.Resonancewilloccurwhenaforceisappliedtoanoscillatingsystematthe45.Supposeyousendapulsealongarope.samefrequencyasthenaturalfrequencyHowdoesthepositionofapointontheofthesystem.ropebeforethepulsearrivescomparetothepoint’spositionafterthepulsehaspassed?40.Howmanygeneralmethodsofenergy(14.2)transferarethere?GivetwoexamplesOncethepulsehaspassed,thepointisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofeach.(14.2)exactlyasitwaspriortotheadventofTwo.Energyistransferredbyparticlethepulse.transferandbywaves.Therearemanyexamplesthatcanbegivenofeach:abaseballandabulletforparticletransfer;soundwavesandlightwaves.Physics:PrinciplesandProblemsSolutionsManual315
319Chapter14continued46.Whatisthedifferencebetweenawavepulse53.Whenawavecrossesaboundarybetweenandaperiodicwave?(14.2)athinandathickrope,asshowninApulseisasingledisturbanceinaFigure14-18,itswavelengthandspeedmedium,whereasaperiodicwavecon-change,butitsfrequencydoesnot.Explainsistsofseveraladjacentdisturbances.whythefrequencyisconstant.(14.3)47.Describethedifferencebetweenwavefrequencyandwavevelocity.(14.2)■Figure14-18FrequencyisthenumberofvibrationsThefrequencydependsonlyontheratepersecondofapartofthemedium.atwhichthethinropeisshakenandtheVelocitydescribesthemotionofthethinropecausesthevibrationsinthewavethroughthemedium.thickrope.48.Supposeyouproduceatransversewaveby54.Howdoesaspringpulsereflectedfromashakingoneendofaspringfromsidetorigidwalldifferfromtheincidentpulse?side.Howdoesthefrequencyofyourhand(14.3)comparewiththefrequencyofthewave?Thereflectedpulsewillbeinverted.(14.2)Theyarethesame.55.Describeinterference.Isinterferenceaprop-ertyofonlysometypesofwavesoralltypes49.Whenarepointsonawaveinphasewithofwaves?(14.3)eachother?Whenaretheyoutofphase?ThesuperpositionoftwoormoreGiveanexampleofeach.(14.2)wavesisinterference.Thesuperposi-Pointsareinphasewhentheyhavetionoftwowaveswithequalbutoppo-thesamedisplacementandthesamesiteamplitudesresultsindestructivevelocity.Otherwise,thepointsareoutinterference.Thesuperpositionoftwoofphase.Twocrestsareinphasewithwaveswithamplitudesinthesameeachother.Acrestandatroughareoutdirectionresultsinconstructiveinter-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofphasewitheachother.ference;allwaves;itisaprimetestforwavenature.50.Whatistheamplitudeofawaveandwhatdoesitrepresent?(14.2)56.WhathappenstoaspringatthenodesofaAmplitudeisthemaximumdisplace-standingwave?(14.3)mentofawavefromtherestorequilib-Nothing,thespringdoesnotmove.riumposition.Theamplitudeofthewaverepresentstheamountofenergy57.ViolinsAmetalplateisheldfixedinthetransferred.centerandsprinkledwithsugar.Withaviolinbow,theplateisstrokedalongone51.Describetherelationshipbetweentheedgeandmadetovibrate.Thesugarbeginsamplitudeofawaveandtheenergyittocollectincertainareasandmoveawaycarries.(14.2)fromothers.DescribetheseregionsintermsTheenergycarriedbyawaveispropor-ofstandingwaves.(14.3)tionaltothesquareofitsamplitude.Bareareasareantinodalregionswherethereismaximumvibration.Sugar-52.Whenawavereachestheboundaryofacoveredareasarenodalregionswherenewmedium,whathappenstoit?(14.3)thereisnovibration.Partofthewavecanbereflectedandpartofthewavecanbetransmittedintothenewmedium.316SolutionsManualPhysics:PrinciplesandProblems
320Chapter14continued58.Ifastringisvibratinginfourparts,thereare62.Supposeyouholda1-mmetalbarinyourpointswhereitcanbetouchedwithouthandandhititsendwithahammer,first,disturbingitsmotion.Explain.Howmanyinadirectionparalleltoitslength,andofthesepointsexist?(14.3)second,inadirectionatrightanglestoitsAstandingwaveexistsandthestringlength.Describethewavesproducedinthecanbetouchedatanyofitsfivenodaltwocases.points.Inthefirstcase,longitudinalwaves;inthesecondcase,transversewaves.59.Wavefrontspassatananglefromonemediumintoasecondmedium,wherethey63.Supposeyourepeatedlydipyourfingerintotravelwithadifferentspeed.Describetwoasinkfullofwatertomakecircularwaves.changesinthewavefronts.WhatdoesnotWhathappenstothewavelengthasyouchange?(14.3)moveyourfingerfaster?ThewavelengthanddirectionoftheThefrequencyofthewaveswillwavefrontschange.Thefrequencyincrease;thespeedwillremainthedoesnotchange.same;thewavelengthwilldecrease.ApplyingConcepts64.Whathappenstotheperiodofawaveasthefrequencyincreases?page39760.AballbouncesupanddownontheendofAsthefrequencyincreases,theperiodaspring.Describetheenergychangesthatdecreases.takeplaceduringonecompletecycle.Doesthetotalmechanicalenergychange?65.Whathappenstothewavelengthofawaveasthefrequencyincreases?Atthebottomofthemotion,theelasticpotentialenergyisatamaximum,whileAsthefrequencyincreases,thewave-gravitationalpotentialenergyisatalengthdecreases.minimumandthekineticenergyiszero.66.SupposeyoumakeasinglepulseonaAttheequilibriumposition,theKEisatstretchedspring.Howmuchenergyisamaximumandtheelasticpotentialrequiredtomakeapulsewithtwicetheenergyiszero.Atthetopofthebounce,amplitude?theKEiszero,thegravitationalpotentialenergyisatamaximum,andtheelasticapproximatelytwosquared,orfourpotentialenergyisatamaximum.Thetimestheenergytotalmechanicalenergyisconserved.67.Youcanmakewatersloshbackandforthin61.Canapendulumclockbeusedintheorbit-ashallowpanonlyifyoushakethepaningInternationalSpaceStation?Explain.withthecorrectfrequency.Explain.No,thespacestationisinfree-fall,andTheperiodofthevibrationmustequaltherefore,theapparentvalueofgisthetimeforthewavetogobackandzero.Thependulumwillnotswing.forthacrossthepantocreateconstruc-tiveinterference.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual317
321Chapter14continued68.IneachofthefourwavesinFigure14-19,70.CarShocksEachofthecoilspringsofathepulseontheleftistheoriginalpulsecarhasaspringconstantof25,000N/m.movingtowardtheright.ThecenterpulseisHowmuchiseachspringcompressedifitareflectedpulse;thepulseontherightisasupportsone-fourthofthecar’s12,000-Ntransmittedpulse.Describetherigidityofweight?theboundariesatA,B,C,andD.F�kx,FAsox��k1����(12,000N)4���25,000N/mB�0.12m71.HowmuchpotentialenergyisstoredinaCspringwithaspringconstantof27N/mifitisstretchedby16cm?12PE�sp�2kxD����1(27N/m)(0.16m)2�0.35J2■Figure14-19Level2BoundaryAismorerigid;boundaryB72.RocketLauncherAtoyrocket-launcherislessrigid;boundaryCislessrigid;containsaspringwithaspringconstantofboundaryDismorerigid.35N/m.HowfarmustthespringbeMasteringProblemscompressedtostore1.5Jofenergy?14.1PeriodicMotion12,PE�sp�2kxpages397–398Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2PEsp(2)(1.5J)Level1sox���������k35N/m69.Aspringstretchesby0.12mwhensomeapplesweighing3.2Naresuspendedfrom�0.29mit,asshowninFigure14-20.Whatisthespringconstantofthespring?Level373.Force-versus-lengthdataforaspringareplottedonthegraphinFigure14-21.12.08.0Force(N)4.03.2N0.00.200.400.60■Figure14-20Length(m)F�kx,■Figure14-21F3.2Nsok�����27N/mx0.12m318SolutionsManualPhysics:PrinciplesandProblems
322Chapter14continueda.Whatisthespringconstantofthe1f���spring?T11k�slopeT������8.3sf0.12Hz�F12.0N�4.0N�������x0.6m�0.2m76.OceanWavesAnoceanwavehasalength�20N/mof12.0m.Awavepassesafixedlocationb.Whatistheenergystoredinthespringevery3.0s.Whatisthespeedofthewave?whenitisstretchedtoalengthof11v��f������(12.0m)����50.0cm?T3.0s1�4.0m/sPE�sp�area�2bh177.Waterwavesinashallowdishare6.0-cm����(0.500m)(10.0N)�2.50J2long.Atonepoint,thewatermovesupanddownatarateof4.8oscillations/s.74.Howlongmustapendulumbetohaveaa.Whatisthespeedofthewaterwaves?periodof2.3sontheMoon,where2?v��fg�1.6m/slT2g�(0.060m)(4.8Hz)�0.29m/sT�2��,sol����g4�2b.Whatistheperiodofthewaterwaves?(2.3s)2(1.6m/s2)11�����0.21mT��f���4.8Hz�0.21s4�278.Waterwavesinalaketravel3.4min1.8s.14.2WavePropertiesTheperiodofoscillationis1.1s.page398a.Whatisthespeedofthewaterwaves?Level175.BuildingMotionTheSearsTowerind3.4mv������1.9m/st1.8sChicago,showninFigure14-22,swaysbackandforthinthewindwithafrequencyb.Whatistheirwavelength?ofabout0.12Hz.Whatisitsperiodofv�����vTvibration?f�(1.9m/s)(1.1s)�2.1mLevel279.SonarAsonarsignaloffrequency1.00�106Hzhasawavelengthof1.50mminwater.a.Whatisthespeedofthesignalinwater?v��f�(1.50�10�3m)(1.00�106Hz)�1.50�103m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Whatisitsperiodinwater?11T������f1.00�106Hz�1.00�10�6s■Figure14-22Physics:PrinciplesandProblemsSolutionsManual319
323Chapter14continuedc.Whatisitsperiodinair?v��f1.00�10�6s�(6.0m)(0.60Hz)Theperiodandfrequencyremain�3.6m/sunchanged.83.EarthquakesThevelocityofthetrans-80.Asoundwaveofwavelength0.60mandaversewavesproducedbyanearthquakeisvelocityof330m/sisproducedfor0.50s.8.9km/s,andthatofthelongitudinalwavesis5.1km/s.Aseismographrecordsa.Whatisthefrequencyofthewave?thearrivalofthetransversewaves68sv��fbeforethearrivalofthelongitudinalv330m/swaves.Howfarawayistheearthquake?f�������0.60md�vt.Wedonotknowt,onlythe�550Hzdifferenceintime,�t.Thetransverseb.Howmanycompletewavesareemitteddistance,dT�vTt,isthesameastheinthistimeinterval?longitudinaldistance,dL�vL(t��t).ft�(550Hz)(0.50s)UsevTt�vL(t��t),andsolvefort:�280completewavesvL�tc.After0.50s,howfaristhefrontofthet��vT�vLwavefromthesourceofthesound?(5.1km/s)(68s)d�vtt�����91s8.9km/s�5.1km/s�(330m/s)(0.50s)Thenputtingtbackinto�1.6�102mdT�vTt�(8.9km/s)(91s)81.Thespeedofsoundinwateris1498m/s.A�8.1�102kmsonarsignalissentstraightdownfromashipatapointjustbelowthewatersurface,14.3WaveBehaviorand1.80slater,thereflectedsignalisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pages398–399detected.Howdeepisthewater?Level1Thetimeforthewavetotraveldown84.Sketchtheresultforeachofthethreecasesandbackupis1.80s.ThetimeonewayshowninFigure14-23,whenthecentersishalf1.80sor0.900s.ofthetwoapproachingwavepulseslieond�vtthedashedlinesothatthepulsesexactly�(1498m/s)(0.900s)overlap.�1350m1Level382.PepeandAlfredoarerestingonanoffshore2raftafteraswim.Theyestimatethat3.0mseparatesatroughandanadjacentcrestofeachsurfacewaveonthelake.Theycount12creststhatpassbytheraftin20.0s.3Calculatehowfastthewavesaremoving.��(2)(3.0m)�6.0m12wavesf����0.60Hz20.0s■Figure14-23320SolutionsManualPhysics:PrinciplesandProblems
324Chapter14continued1.Theamplitudeisdoubled.15cmfromtheotherend,wherethedistancestraveledarethesame.87.SketchtheresultforeachofthefourcasesshowninFigure14-24,whenthecentersof2.Theamplitudescanceleachother.eachofthetwowavepulseslieonthedashedlinesothatthepulsesexactlyoverlap.3.Iftheamplitudeofthefirstpulseis1one-halfofthesecond,theresultantpulseisone-halftheamplitudeofthesecond.2385.Ifyousloshthewaterinabathtubatthecorrectfrequency,thewaterrisesfirstatoneendandthenattheother.Supposeyoucan4makeastandingwaveina150-cm-longtubwithafrequencyof0.30Hz.Whatisthevelocityofthewaterwave?■Figure14-24��2(1.5m)�3.0mv��f�(3.0m)(0.30Hz)1�0.90m/sLevel2286.GuitarsThewavespeedinaguitarstringis265m/s.Thelengthofthestringis63cm.You3pluckthecenterofthestringbypullingitupandlettinggo.Pulsesmoveinbothdirectionsandarereflectedofftheendsofthestring.4a.Howlongdoesittakeforthepulsetomovetothestringendandreturntothecenter?(2)(63cm)d����63cmMixedReview2page399–400sot�d���0.63m�2.4�10�3s�Level1v265m/s88.Whatistheperiodofapendulumwithab.Whenthepulsesreturn,isthestringlengthof1.4m?aboveorbelowitsrestinglocation?lPulsesareinvertedwhenreflectedT�2�����gCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.fromamoredensemedium,soreturningpulseisdown(below).1.4m�2����2.4s��9.80m/s2c.Ifyoupluckedthestring15cmfromoneendofthestring,wherewouldthe89.Thefrequencyofyellowlightis5.1�1014Hz.twopulsesmeet?Findthewavelengthofyellowlight.Thespeedoflightis3.00�108m/s.Physics:PrinciplesandProblemsSolutionsManual321
325Chapter14continuedcc.Inthecourseof15syoucountten����fwavesthatpassyou.Whatistheperiod3.00�108m/softhewaves?���5.1�1014Hz15sT����1.5s10waves�5.9�10�7md.Whatisthefrequencyofthewaves?90.RadioWaveAM-radiosignalsarebroad-11f�������0.67Hzcastatfrequenciesbetween550kHzT1.5s(kilohertz)and1600kHzandtravele.Youestimatethatthewavecrestsare3m3.0�108m/s.apart.Whatisthevelocityofthewaves?a.Whatistherangeofwavelengthsforv��f�(3m)(0.67Hz)�2m/sthesesignals?f.Afterreturningtothebeach,youlearnv��fthatthewavesaremovingat1.8m/s.Whatistheactualwavelengthofthev3.0�108m/s�1��f����5.5�105Hzwaves?1v1.8m/s�550m��������2.7mf0.67Hzv3.0�108m/s������2�f1.6�106HzLevel2292.BungeeJumperAhigh-altitudebungee�190mjumperjumpsfromahot-airballoonusingRangeis190mto550m.a540-m-bungeecord.Whenthejumpisb.FMfrequenciesrangebetween88MHzcompleteandthejumperisjustsuspended(megahertz)and108MHzandtravelfromthecord,itisstretched1710m.Whatatthesamespeed.WhatistherangeofisthespringconstantofthebungeecordifFMwavelengths?thejumperhasamassof68kg?v3.0�108m/sFmg(68kg)(9.80m/s2)���f����8.8�107Hzk����������xx1710m�540mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�3.4m�0.57N/mv3.0�108m/s�������8Hz93.Thetimeneededforawaterwavetochangef1.08�10fromtheequilibriumleveltothecrestis�2.8m0.18s.Rangeis2.8mto3.4m.a.Whatfractionofawavelengthisthis?191.Youarefloatingjustoffshoreatthebeach.�wavelength4Eventhoughthewavesaresteadilyb.Whatistheperiodofthewave?movingintowardthebeach,youdon’tmoveanyclosertothebeach.T�(4)(0.18s)�0.72sa.Whattypeofwaveareyouexperiencingc.Whatisthefrequencyofthewave?asyoufloatinthewater?11f������1.4HztransversewavesT0.72sb.Explainwhytheenergyinthewave94.Whena225-gmassishungfromaspring,doesnotmoveyouclosertoshore.thespringstretches9.4cm.ThespringandThedisplacementisperpendicularmassthenarepulled8.0cmfromthisnewtothedirectionofthewave—inequilibriumpositionandreleased.Findthethiscase,upanddown.springconstantofthespringandthemaxi-mumspeedofthemass.322SolutionsManualPhysics:PrinciplesandProblems
326Chapter14continuedFmgNew:k�����xxT2l�g��(0.225kg)(9.80m/s2)4�2�����23N/m0.094m(1.0�101s)2�(9.80m/s2)��Maximumvelocityoccurswhenthemass4�2passesthroughtheequilibriumpoint,�25mwherealltheenergyiskineticenergy.ThearmonthenewstructureisUsingtheconservationofenergy:11mlonger.PEsp�KEmasse.Iftheparkownerswantedtodoublethe12�12periodoftheride,whatpercentage��kx��mv22increasewouldneedtobemadetothe2lengthofthependulum?2�kxv�mBecauseofthesquarerelationship,kx2(23N/m)(0.080m)2therewouldneedtobea4timesv����m�������0.225kgincreaseinthelengthofthependu-lum,ora300%increase.�0.81m/s96.ClocksThespeedatwhichagrandfather95.AmusementRideYounoticethatyourclockrunsiscontrolledbyaswingingfavoriteamusement-parkrideseemsbigger.pendulum.Therideconsistsofacarriagethatisa.Ifyoufindthattheclocklosestimeattachedtoastructuresoitswingslikeaeachday,whatadjustmentwouldyoupendulum.Yourememberthatthecarriageneedtomaketothependulumsoitwillusedtoswingfromonepositiontoanotherkeepbettertime?andbackagaineighttimesinexactly1min.Nowitonlyswingssixtimesin1min.GiveTheclockmustbemadetorunyouranswerstothefollowingquestionstofaster.Theperiodofthependulumtwosignificantdigits.canbeshortened,thusincreasingthespeedoftheclock,byshorten-a.Whatwastheoriginalperiodoftheride?ingthelengthofthependulum.11T������7.5sb.Ifthependulumcurrentlyis15.0cm,f8swings����byhowmuchwouldyouneedto60.0schangethelengthtomaketheperiodb.Whatisthenewperiodoftheride?lessenby0.0400s?111sT������1.0�10f6swingsl2l1�����T�2������2�����60.0sggc.Whatisthenewfrequency?�Tl2l111�2������g�����g�f�������0.10HzT1.0�10�1s�T11d.Howmuchlongeristhearmsupporting�2������g���l2����g���l1thecarriageonthelargerride?�T11Original:�2������l�2�����l1�g��g�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.T2l�g��4�2�T�g��2�����l2��l�1(7.5s)2�(9.80m/s2)�4�2�14mPhysics:PrinciplesandProblemsSolutionsManual323
327Chapter14continued�T�g���l2��2����l�1�T�g�2l2���2�����l1�(�0.0400s)�9.80m�/s�22�������0.150��m�2��0.135mThelengthwouldneedtoshortenbyl1�l2�0.150m�0.135m�0.015m97.BridgeSwingingInthesummerovertheNewRiverinWestVirginia,severalteensswingfrombridgeswithropes,thendropintotheriverafterafewswingsbackandforth.a.IfPamisusinga10.0-mlengthofrope,howlongwillittakehertoreachthepeakofherswingattheotherendofthebridge?1swingtopeak��T2l10.0m���������3.17s��g��9.80m/s2b.IfMikehasamassthatis20kgmorethanPam,howwouldyouexpecttheperiodofhisswingtodifferfromPam’s?Thereshouldbenodifference.Tisnotaffectedbymass.c.AtwhatpointintheswingisKEatamaximum?Atthebottomoftheswing,KEisatamaximum.d.AtwhatpointintheswingisPEatamaximum?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Atthetopoftheswing,PEisatamaximum.e.AtwhatpointintheswingisKEataminimum?Atthetopoftheswing,KEisataminimum.f.AtwhatpointintheswingisPEataminimum?Atthebottomoftheswing,PEisataminimum.98.Youhaveamechanicalfishscalethatismadewithaspringthatcompresseswhenweightisaddedtoahookattachedbelowthescale.Unfortunately,thecalibrationshavecompletelywornoffofthescale.However,youhaveoneknownmassof500.0gthatdisplacesthespring2.0cm.a.Whatisthespringconstantforthespring?F�mg�kxmgk��x(0.5000kg)(9.80m/s2)����0.020m�2.4�102N/mb.Ifafishdisplacesthespring4.5cm,whatisthemassofthefish?F�mg�kx324SolutionsManualPhysics:PrinciplesandProblems
328Chapter14continuedkxFm���TgNowv�����,so�(2.4�102N/m)(4.5�10�2m)F2������T�v9.80m/s2�(1.50�102m/s)2(2.83�10�3kg/m)�1.1kg�63.7N99.CarSpringsWhenyouadda45-kgloadtothetrunkofanewsmallcar,thetworearThinkingCriticallyspringscompressanadditional1.0cm.page400a.Whatisthespringconstantforeachof101.AnalyzeandConcludeA20-Nforceisthesprings?requiredtostretchaspringby0.5m.F�mg�(45kg)(9.80m/s2)�440Na.Whatisthespringconstant?forceperspring�220NF20NF�kx,sok�������40N/mx0.5mFF�kx,sok���xb.Howmuchenergyisstoredinthespring?220Nk����22,000N/m0.010m12PE�sp�2kxb.Howmuchadditionalpotentialenergyisstoredineachofthecarsprings����1(40N/m)(0.5m)2�5J2afterloadingthetrunk?c.Whyisn’ttheworkdonetostretchthe12PE��kxspringequaltotheforcetimesthe2distance,or10J?12����(22,000N/m)(0.010m)2Theforceisnotconstantasthe�1.1Jspringisstretched.Theaverageforce,10N,timesthedistanceLevel3doesgivethecorrectwork.100.Thevelocityofawaveonastringdepends102.MakeandUseGraphsSeveralweightsonhowtightlythestringisstretched,andweresuspendedfromaspring,andtheonthemassperunitlengthofthestring.IfresultingextensionsofthespringwereFTisthetensioninthestring,and�isthemeasured.Table14-1showsthemass/unitlength,thenthevelocity,v,cancollecteddata.bedeterminedbythefollowingequation.Fv�����TTable14-1�WeightsonaSpringApieceofstring5.30-mlonghasamassForce,F(N)Extension,x(m)of15.0g.Whatmustthetensionin2.50.12thestringbetomakethewavelengthofa5.00.26125-Hzwave120.0cm?7.50.35v��f�(1.200m)(125Hz)10.00.50�1.50�102m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12.50.60mand����15.00.71L1.50�10�2kg���5.30m�2.83�10�3kg/mPhysics:PrinciplesandProblemsSolutionsManual325
329Chapter14continueda.Makeagraphoftheforceappliedtothespringversusthespringlength.Plottheforceonthey-axis.20.015.010.0Force(N)5.00.00.200.400.600.80Stretch(m)b.Determinethespringconstantfromthegraph.Thespringconstantistheslope.�F15.0N�2.5Nk�slope�������21N/m�x0.71m�0.12mc.Usingthegraph,findtheelasticpotentialenergystoredinthespringwhenitisstretchedto0.50m.Thepotentialenergyistheareaunderthegraph.1PE��bhsp�area�21�����(0.50m)(10.0N)2�2.5J103.ApplyConceptsGravelroadsoftendevelopregularlyspacedridgesthatareperpendiculartotheroad,asshowninFigure14-25.Thiseffect,calledwashboarding,occursbecausemostcarstravelataboutthesamespeedandCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thespringsthatconnectthewheelstothecarsoscillateataboutthesamefrequency.Iftheridgesonaroadare1.5mapartandcarstravelonitatabout5m/s,whatisthefrequencyofthesprings’oscillation?■Figure14-25v��fv5m/sf�������3Hz�1.5m326SolutionsManualPhysics:PrinciplesandProblems
330Chapter14continuedWritinginPhysicsc.Whatwastheaverageaccelerationoftheautomobile?page400104.ResearchChristiaanHuygens’workona�����v�twavesandthecontroversybetweenhimandNewtonoverthenatureoflight.112m/s���9.8sCompareandcontrasttheirexplanationsofsuchphenomenaasreflectionandrefrac-�11m/s2tion.Whosemodelwouldyouchooseasthebestexplanation?Explainwhy.106.Howmuchwaterwouldasteamenginehavetoevaporatein1stoproduce1kWHuygensproposedthewavetheoryofpower?AssumethattheengineisoflightandNewtonproposedthe20percentefficient.(Chapter12)particletheoryoflight.ThelawofreflectioncanbeexplainedusingW���1000J/stboththeories.Huygen’sprincipleandNewton’sparticletheoryareopposed,Iftheengineisonly20percenthowever,intheirexplanationoftheefficientitmustusefivetimesmorelawofrefraction.heattoproducethe1000J/s.QmHv���5000J/s���CumulativeReviewttpage400m5000J/sTherefore,�����105.A1400-kgdragracerautomobilecantHvcompleteaone-quartermile(402m)5000J/s���coursein9.8s.Thefinalspeedofthe2.26�106J/kgautomobileis250mi/h(112m/s).�2�10�3kg/s(Chapter11)a.Whatisthekineticenergyoftheautomobile?ChallengeProblemKE��1mv2page3802Acarofmassmrestsatthetopofahillof����1(1400kg)(112m/s)2heighthbeforerollingwithoutfrictionintoa2crashbarrierlocatedatthebottomofthehill.�8.8�106JThecrashbarriercontainsaspringwithaspringb.Whatistheminimumamountofworkconstant,k,whichisdesignedtobringthecartothatwasdonebyitsengine?Whycan’trestwithminimumdamage.youcalculatethetotalamountofwork1.Determine,intermsofm,h,k,andg,thedone?maximumdistance,x,thatthespringwillTheminimumamountofworkbecompressedwhenthecarhitsit.mustequalKE,or8.8�106J.TheConservationofenergyimpliesthattheenginehadtodomoreworkthangravitationalpotentialenergyofthecarwasdissipatedinworkdoneatthetopofthehillwillbeequaltotheagainstfriction.elasticpotentialenergyinthespringwhenithasbroughtthecartorest.TheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.equationsfortheseenergiescanbesetequalandsolvedforx.12PE��kxg�PEsp,somgh�22mghx����kPhysics:PrinciplesandProblemsSolutionsManual327
331Chapter14continued2.Ifthecarrollsdownahillthatistwiceashigh,howmuchfartherwillthespringbecompressed?Theheightisdoubledandxispropor-tionaltothesquarerootoftheheight,soxwillincreaseby�2�.3.Whatwillhappenafterthecarhasbeenbroughttorest?Inthecaseofanidealspring,thespringwillpropelthecarbacktothetopofthehill.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.328SolutionsManualPhysics:PrinciplesandProblems
332CHAPTER15SoundvPracticeProblemss��24.6m/s115.1PropertiesandDetectionf��d�524Hz��1��(�24.6�m/s)ofSound343m/spages403–410�489Hzpage4051.Findthewavelengthinairat20°Cofan7.Youareinanautotravelingat25.0m/s18-Hzsoundwave,whichisoneofthetowardapole-mountedwarningsiren.Iflowestfrequenciesthatisdetectablebythethesiren’sfrequencyis365Hz,whathumanear.frequencydoyouhear?Use343m/sasthespeedofsound.v343m/s��������19mf18Hzv�343m/s,fs�365Hz,vs�0,2.Whatisthewavelengthofan18-Hzsoundvd��25.0m/swaveinseawaterat25°C?v�vf��d�v1533m/sd�fs�v�v��������85msf18Hz343m/s�25.0m/s3.Findthefrequencyofasoundwavemoving�(365Hz)�����343m/sthroughironat25°Cwithawavelengthof�392Hz1.25m.f��v���5130�m/s�4.10�103Hz8.Youareinanautotravelingat55mph�1.25m(24.6m/s).Asecondautoismovingtoward4.Ifyoushoutacrossacanyonandheartheyouatthesamespeed.Itshornissoundingecho0.80slater,howwideisthecanyon?at475Hz.Whatfrequencydoyouhear?dUse343m/sasthespeedofsound.v���tv�343m/s,fs�475Hz,vs��24.6m/s,sod�vt�(343m/s)(0.40s)�140mvd��24.6m/sv�v5.A2280-Hzsoundwavehasawavelengthoff��d�d�fs�v�v0.655minanunknownmedium.Identifysthemedium.343m/s�24.6m/s�(475Hz)�����v343m/s�24.6m/s����f�548Hzsov��f�(0.655m)(2280Hz)9.Asubmarineismovingtowardanother�1490m/ssubmarineat9.20m/s.Itemitsa3.50-MHzThisspeedcorrespondstowateratultrasound.Whatfrequencywouldthe25°C.secondsub,atrest,detect?ThespeedofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.soundinwateris1482m/s.v�1482m/s,fs�3.50MHz,page4096.RepeatExampleProblem1,butwiththecarvs�9.20m/s,vd�0m/smovingawayfromyou.Whatfrequencyv�vf��d�wouldyouhear?d�fs�v�vsPhysics:PrinciplesandProblemsSolutionsManual329
333Chapter15continued1482m/s13.SoundPropertiesWhatphysicalcharac-�(3.50MHz)�����1482m/s�9.20m/steristicofasoundwaveshouldbechanged�3.52MHztochangethepitchofthesound?Tochangetheloudness?10.AsoundsourceplaysmiddleC(262Hz).frequency;amplitudeHowfastwouldthesourcehavetogotoraisethepitchtoCsharp(271Hz)?Use14.DecibelScaleHowmuchgreateristhe343m/sasthespeedofsound.soundpressurelevelofatypicalrockband’sv�343m/s,fmusic(110dB)thananormalconversations�262Hz,fd�271Hz,(50dB)?vd�0m/s,vsisunknownThesoundpressurelevelincreasesbyv�vf��d�afactorof10forevery20-dBincreased�fs�v�vsinsoundlevel.Therefore,60dBcorre-Solvethisequationforvspondstoa1000-foldincreaseinSPL.s.fv�s�(v�v15.EarlyDetectionInthenineteenthcentury,s�v�fd)dpeopleputtheirearstoarailroadtrackto262Hzgetanearlywarningofanapproaching�343m/s���271�Hz�(343m/s�0m/s)train.Whydidthiswork?�11.4m/sThevelocityofsoundisgreaterinsolidsthaningases.Therefore,soundtravelsfasterinsteelrailsthaninair,SectionReviewandtherailshelpfocusthesoundsoitdoesnotdieoutasquicklyasinair.15.1PropertiesandDetectionofSound16.BatsAbatemitsshortpulsesofhigh-pages403–410frequencysoundanddetectstheechoes.page410a.InwhatwaywouldtheechoesfromCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.11.GraphTheeardrummovesbackandforthlargeandsmallinsectscompareiftheyinresponsetothepressurevariationsofawerethesamedistancefromthebat?soundwave.Sketchagraphofthedisplace-Theywoulddifferinintensity.Largermentoftheeardrumversustimefortwoinsectswouldreflectmoreofthecyclesofa1.0-kHztoneandfortwocyclessoundenergybacktothebat.ofa2.0-kHztone.b.InwhatwaywouldtheechofromaninsectflyingtowardthebatdifferfromthatofaninsectflyingawayfromtheTime(ms)bat?0.51.01.52.0AninsectflyingtowardthebatDisplacementwouldreturnanechoofhigherfre-1.0kHzquency(Dopplershift).Aninsectfly-2.0kHzingawayfromthebatwouldreturnanechooflowerfrequency.12.EffectofMediumListtwosoundcharac-teristicsthatareaffectedbythemedium17.CriticalThinkingCanatrooperusingathroughwhichthesoundpassesandtworadardetectoratthesideoftheroadcharacteristicsthatarenotaffected.determinethespeedofacarattheinstantaffected:speedandwavelength;thecarpassesthetrooper?Explain.unaffected:periodandfrequencyNo.Thecarmustbeapproachingor330SolutionsManualPhysics:PrinciplesandProblems
334Chapter15continuedrecedingfromthedetectorforthev343m/sf������64.7Hz1��5.30mDopplereffecttobeobserved.1Transversemotionproducesnob.FindthenexttworesonantfrequenciesDopplereffect.forthebugle.vv343m/sf���������129Hz2��L2.65mPracticeProblems2v3v(3)(343m/s)f���������194Hz15.2ThePhysicsofMusic3��2L(2)(2.65m)3pages411–419page416SectionReview18.A440-Hztuningforkisheldaboveaclosed15.2ThePhysicsofMusicpipe.Findthespacingbetweenthereso-nanceswhentheairtemperatureis20°C.pages411–419�vpage419Resonancespacing���sousing����2f22.OriginsofSoundWhatisthevibratingtheresonancespacingisobjectthatproducessoundsineachofthe�v343m/s���������0.39mfollowing?22f(2)(440Hz)a.ahumanvoice19.A440-Hztuningforkisusedwithavocalcordsresonatingcolumntodeterminetheb.aclarinetvelocityofsoundinheliumgas.Ifthespacingsbetweenresonancesare110cm,areedwhatisthevelocityofsoundinheliumgas?c.atuba�Resonancespacing����1.1mtheplayer’slips2so��2.2md.aviolinv��f�(2.2m)(440Hz)�970m/sastring20.Thefrequencyofatuningforkisunknown.23.ResonanceinAirColumnsWhyistheAstudentusesanaircolumnat27°Candtubefromwhichatubaismademuchfindsresonancesspacedby20.2cm.Whatlongerthanthatofacornet?isthefrequencyofthetuningfork?UsetheThelongerthetube,thelowerthespeedcalculatedinExampleProblem2forresonantfrequencyitwillproduce.thespeedofsoundinairat27°C.v�347m/sat27°C24.ResonanceinOpenTubesHowmustthe�lengthofanopentubecomparetotheResonancespacinggives���0.202m,2wavelengthofthesoundtoproducetheor��0.404mstrongestresonance?v347m/sf�������859HzThelengthofthetubeshouldbe�0.404mone-halfthewavelength.21.Abuglecanbethoughtofasanopenpipe.Ifabuglewerestraightenedout,itwouldbe25.ResonanceonStringsAviolinsoundsa2.65-mlong.noteofFsharp,withapitchof370Hz.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Ifthespeedofsoundis343m/s,findWhatarethefrequenciesofthenextthreethelowestfrequencythatisresonantforharmonicsproducedwiththisnote?abugle(ignoringendcorrections).Astring’sharmonicsarewholenumber�multiplesofthefundamental,sothefre-1�2L�(2)(2.65m)�5.30mquenciesare:ThelowestfrequencyisPhysics:PrinciplesandProblemsSolutionsManual331
335Chapter15continuedfgreatlywhenitispressedagainstother2�2f1�(2)(370Hz)�740Hzfobjectsbecausetheyresonatelikea3�3f1�(3)(370Hz)�1110Hzsoundingboard.Theysounddifferent�1100Hzbecausetheyresonatewithdifferentf4�4f1�(4)(370Hz)�1480Hzharmonics;therefore,theyhavedifferent�1500Hztimbres.26.ResonanceinClosedPipesOneclosedorganpipehasalengthof2.40m.ChapterAssessmenta.WhatisthefrequencyofthenoteConceptMappingplayedbythispipe?page424��4L�(4)(2.40m)�9.60m30.Completetheconceptmapbelowusingthev����followingterms:amplitude,perception,pitch,fspeed.v343m/sf�������35.7Hz�9.60mSoundb.Whenasecondpipeisplayedatthesametime,a1.40-Hzbeatnoteisheard.Byhowmuchisthesecondpipetoopropertiesperceptionlong?f�35.7Hz�1.40Hz�34.3Hzfrequencypitchloudnessv343m/s��������10.0mf34.3Hzspeed��4Lamplitude�10.0mL�������2.50m44ThedifferenceinlengthsisMasteringConceptsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2.50m�2.40m�0.10mpage42427.TimbreWhydovariousinstrumentssound31.Whatarethephysicalcharacteristicsofdifferentevenwhentheyplaythesamenote?soundwaves?(15.1)EachinstrumentproducesitsownsetSoundwavescanbedescribedbyoffundamentalandharmonicfrequen-frequency,wavelength,amplitude,cies,sotheyhavedifferenttimbres.andspeed.28.BeatsAtuningforkproducesthreebeats32.Whentimingthe100-mrun,officialsatthepersecondwithasecond,392-Hztuningfinishlineareinstructedtostarttheirstop-fork.Whatisthefrequencyofthefirstwatchesatthesightofsmokefromthetuningfork?starter’spistolandnotatthesoundofitsfiring.Explain.WhatwouldhappentotheItiseither389Hzor395Hz.Youcan’ttimesfortherunnersifthetimingstartedtellwhichwithoutmoreinformation.whensoundwasheard?(15.1)29.CriticalThinkingStrikeatuningforkwithLighttravelsat3.00�108m/s,whilearubberhammerandholditatarm’ssoundtravelsat343m/s.Officialslength.Thenpressitshandleagainstadesk,wouldseethesmokebeforetheywouldadoor,afilingcabinet,andotherobjects.hearthepistolfire.ThetimeswouldbeWhatdoyouhear?Why?lessthanactualifsoundwereused.Thetuningfork’ssoundisamplified332SolutionsManualPhysics:PrinciplesandProblems
336Chapter15continued33.Nametwotypesofperceptionofsoundand39.MusicalInstrumentsWhydon’tmostthephysicalcharacteristicsofsoundwavesmusicalinstrumentssoundliketuningthatcorrespondtothem.(15.1)forks?(15.2)pitch—frequency,loudness—amplitudeTuningforksproducesimple,single-frequencywaves.Musicalinstruments34.DoestheDopplershiftoccurforonlysomeproducecomplexwavescontainingtypesofwavesorforalltypesofwaves?manydifferentfrequencies.Thisgives(15.1)themtheirtimbres.alltypesofwaves40.MusicalInstrumentsWhatpropertydis-35.Soundwaveswithfrequencieshigherthantinguishesnotesplayedonbothatrumpetcanbeheardbyhumans,calledultrasound,andaclarinetiftheyhavethesamepitchcanbetransmittedthroughthehumanbody.andloudness?(15.2)Howcouldultrasoundbeusedtomeasurethesoundqualityortimbrethespeedofbloodflowinginveinsorarter-ies?Explainhowthewaveschangetomake41.TrombonesExplainhowtheslideofathismeasurementpossible.(15.1)trombone,showninFigure15-21,changesDoctorscanmeasuretheDopplershiftthepitchofthesoundintermsofatrom-fromsoundreflectedbythemovingbonebeingaresonancetube.(15.2)bloodcells.Becausethebloodismov-ing,soundgetsDopplershifted,thecompressionseithergetpileduporspacedapart.Thisaltersthefrequencyofthewave.36.Whatisnecessaryfortheproductionandtransmissionofsound?(15.2)avibratingobjectandamaterialmedium■Figure15-21Theslideofatrombonevariespitchby37.SingingHowcanacertainnotesungbyanchangingthelengthoftheresonatingoperasingercauseacrystalglasstoshatter?columnofvibratingair.(15.2)ThefrequencyofthenoteisthesameApplyingConceptsasthenaturalresonanceofthecrystal,pages424–425causingitsmoleculestoincreasetheir42.EstimationToestimatethedistanceinamplitudeofvibrationasenergyfromkilometersbetweenyouandalightningthesoundisaccepted.flash,countthesecondsbetweentheflashandthethunderanddivideby3.Explain38.MarchingInthemilitary,asmarchinghowthisruleworks.Deviseasimilarrulesoldiersapproachabridge,thecommandformiles.“routestep”isgiven.ThesoldiersthenwalkThespeedofsound�343m/s�out-of-stepwitheachotherastheycrossthe0.343km/s�(1/2.92)km/s;or,soundbridge.Explain.(15.2)travelsapproximately1kmin3s.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Whilemarchinginstep,acertainTherefore,dividethenumberofsec-frequencyisestablishedthatcouldondsbythree.Formiles,soundtravelsresonatethebridgeintodestructiveapproximately1milein5s.Therefore,oscillation.Nosinglefrequencyismain-dividethenumberofsecondsbyfive.tainedunder“routestep.”Physics:PrinciplesandProblemsSolutionsManual333
337Chapter15continued43.Thespeedofsoundincreasesbyabout47.Ifthepitchofsoundisincreased,whatare0.6m/sforeachdegreeCelsiuswhenthethechangesinthefollowing?airtemperaturerises.Foragivensound,asa.thefrequencythetemperatureincreases,whathappenstoFrequencywillincrease.thefollowing?b.thewavelengtha.thefrequencyWavelengthwilldecrease.Thereisnochangeinfrequency.c.thewavevelocityb.thewavelengthWavevelocitywillremainthesame.Thewavelengthincreases.d.theamplitudeofthewave44.MoviesInascience-fictionmovie,asatelliteAmplitudewillremainthesame.blowsup.Thecrewofanearbyshipimmedi-atelyhearsandseestheexplosion.Ifyouhad48.Thespeedofsoundincreaseswithtempera-beenhiredasanadvisor,whattwophysicsture.Wouldthepitchofaclosedpipeerrorswouldyouhavenoticedandcorrected?increaseordecreasewhenthetemperatureoftheairrises?AssumethatthelengthofFirst,ifyouhadheardasound,youthepipedoesnotchange.wouldhavehearditafteryousawtheexplosion.Soundwavestravelmuch��4landv�f�sov�4fl.Ifvmoreslowlythanelectromagneticincreasesandlremainsunchanged,fwaves.Second,inspacethedensityofincreasesandpitchincreases.matterissosmallthatthesoundwavesdonotpropagate.Consequently,no49.MarchingBandsTwoflutistsaretuningup.soundshouldhavebeenheard.Iftheconductorhearsthebeatfrequencyincreasing,arethetwoflutefrequenciesget-45.TheRedshiftAstronomershaveobservedtingclosertogetherorfartherapart?thatthelightcomingfromdistantgalaxiesThefrequenciesaregettingfartherappearsredderthanlightcomingfromapart.nearergalaxies.WiththehelpofFigureCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.15-22,whichshowsthevisiblespectrum,50.MusicalInstrumentsAcoveredorganexplainwhyastronomersconcludethatdis-pipeplaysacertainnote.IfthecoveristantgalaxiesaremovingawayfromEarth.removedtomakeitanopenpipe,isthepitchincreasedordecreased?Thepitchisincreased;thefrequencyistwiceashighforanopenpipeasforaclosedpipe.4�10�7m5�10�7m6�10�7m7�10�7m■Figure15-2351.StringedInstrumentsOnaharp,RedlighthasalongerwavelengthandFigure15-23a,longstringsproducelowtherefore,alowerfrequencythanothernotesandshortstringsproducehighnotes.colors.TheDopplershiftoftheirlighttoOnaguitar,Figure15-23b,thestringsarelowerfrequenciesindicatesthatdistantallthesamelength.Howcantheyproducegalaxiesaremovingawayfromus.notesofdifferentpitches?46.Doesasoundof40dBhaveafactorof100(102)timesgreaterpressurevariationthanthethresholdofhearing,orafactorof40timesgreater?A40-dBsoundhassoundpressures100timesgreater.334SolutionsManualPhysics:PrinciplesandProblems
338Chapter15continued■Figure15-23■Figure15-24ThestringshavedifferenttensionsandThetotaldistancethesoundmustmassesperunitlength.Thinner,tightertravelis6.00m.stringsproducehighernotesthandodv���thicker,looserstrings.td6.00msot�������0.0175sMasteringProblemsv343m/s15.1PropertiesandDetectionofSound57.Soundwithafrequencyof261.6Hztravelspages425–426throughwaterat25°C.Findthesound’sLevel1wavelengthinwater.Donotconfusesound52.Youhearthesoundofthefiringofadistantwavesmovingthroughwaterwithsurfacecannon5.0safterseeingtheflash.Howfarwavesmovingthroughwater.areyoufromthecannon?v1493m/s��������5.707md�vt�(343m/s)(5.0s)�1.7kmf261.6Hz58.Ifthewavelengthofa4.40�102-Hzsound53.Ifyoushoutacrossacanyonandhearaninfreshwateris3.30m,whatisthespeedofecho3.0slater,howwideisthecanyon?soundinfreshwater?d�vt�(343m/s)(3.0s)isthetotaldis-2Hz)v��f�(3.30m)(4.40�10tancetraveled.Thedistancetothewall1�1.45�103m/sis��(343m/s)(3.0s)�5.1�102m259.Soundwithafrequencyof442Hztravels54.Asoundwavehasafrequencyof4700Hzthroughanironbeam.Findthewavelengthandtravelsalongasteelrod.Ifthedistanceofthesoundiniron.betweencompressions,orregionsofhighv5130m/spressure,is1.1m,whatisthespeedofthe��������11.6mf442Hzwave?60.AircraftAdam,anairportemployee,isv��f�(1.1m)(4700Hz)�5200m/sworkingnearajetplanetakingoff.He55.BatsThesoundemittedbybatshasaexperiencesasoundlevelof150dB.wavelengthof3.5mm.Whatisthesound’sa.IfAdamwearsearprotectorsthatreducefrequencyinair?thesoundleveltothatofatypicalv343m/s4Hzrockconcert,whatdecreaseindBisf�������9.8�10�0.0035mprovided?56.PhotographyAsshowninFigure15-24,Atypicalrockconcertis110dB,sosomecamerasdeterminethedistancetothe40dBreductionisneeded.subjectbysendingoutasoundwaveandb.IfAdamthenhearssomethingthatmeasuringthetimeneededfortheechotosoundslikeabarelyaudiblewhisper,returntothecamera.Howlongwoulditwhatwillapersonnotwearingtheeartakethesoundwavetoreturntosuchaprotectorshear?cameraifthesubjectwere3.00maway?Abarelyaudiblewhisperis10dB,sotheactuallevelwouldbe50dB,orthatofanaverageclassroom.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.61.RockMusicArockbandplaysatan80-dBsoundlevel.Howmanytimesgreateristhesoundpressurefromanotherrockbandplay-ingateachofthefollowingsoundlevels?3.00mPhysics:PrinciplesandProblemsSolutionsManual335
339Chapter15continueda.100dBLevel2Each20dBincreasespressurebya65.MedicalImagingUltrasoundwithafactorof10,so10timesgreaterfrequencyof4.25MHzcanbeusedtopressure.produceimagesofthehumanbody.Ifthespeedofsoundinthebodyisthesameasb.120dBinsaltwater,1.50km/s,whatisthelength(10)(10)�100timesgreaterpressureofa4.25-MHzpressurewaveinthebody?v1.50�103m/s�4m62.Acoiled-springtoyisshakenatafrequency��������3.53�10f4.25�106Hzof4.0Hzsuchthatstandingwavesareobservedwithawavelengthof0.50m.What�0.353mmisthespeedofpropagationofthewave?66.SonarAshipsurveyingtheoceanbottomv��f�(0.50m)(4.0s�1)�2.0m/ssendssonarwavesstraightdownintotheseawaterfromthesurface.Asillustratedin63.AbaseballfanonawarmsummerdayFigure15-26,thefirstreflection,offofthe(30°C)sitsinthebleachers152mawaymudattheseafloor,isreceived1.74safterfromhomeplate.itwassent.Thesecondreflection,fromthea.Whatisthespeedofsoundinairatbedrockbeneaththemud,returnsafter30°C?2.36s.TheseawaterisatatemperatureofThespeedincreases0.6m/sper°C,25°C,andthespeedofsoundinmudissotheincreasefrom20°Cto30°Cis1875m/s.6m/s.Thus,thespeedis343�6�349m/s.b.Howlongafterseeingtheballhitthebatdoesthefanhearthecrackofthebat?d152mt�1.74st�2.36st�������0.436sv349mSeawaterCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.64.Onadaywhenthetemperatureis15°C,apersonstandssomedistance,d,asshowninFigure15-25,fromacliffandclapshisMudhands.Theechoreturnsin2.0s.Howfarawayisthecliff?Bedrock■Figure15-26a.Howdeepisthewater?Thespeedofsoundintheseawateris1533m/sandthetimeforaone-waytripis0.87s,sodw�vtw�(1533m/s)(0.87s)�1300mb.Howthickisthemud?dTheround-triptimeinthemudis■Figure15-252.36s�1.74s�0.62sAt15°C,thespeedofsoundis3m/sslowerthanat20°C.Thus,thespeedofTheone-waytimeinthemudis0.31s,soundis340m/s.sodm�vtm�(1875m/s)(0.31s)v�340m/sand2t�2.0s�580md�vt�(340m/s)(1.0s)�3.4�102m336SolutionsManualPhysics:PrinciplesandProblems
340Chapter15continued67.Determinethevariationinsoundpressure(305Hz)(343m/s�0)����ofaconversationbeingheldatasound343m/s�(�31.0m/s)levelof60dB.�2.80�102HzThepressurevariationat0dBisb.atrainmovingawayfromthefirsttrain2�10�5Pa.Forevery20-dBincrease,theataspeedof21.0m/spressurevariationincreasesbyafactorv�vf��d�of10.Therefore,60dBhasapressured�fs�v�vsvariationamplitudeof2�10�2Pa.(305Hz)(343m/s�21.0m/s)�����343m/s�(�31.0m/s)68.Afiretruckismovingat35m/s,andacarinfrontofthetruckismovinginthesame�2.63�102Hzdirectionat15m/s.Ifa327-Hzsirenblaresfromthetruck,whatfrequencyisheardby15.2ThePhysicsofMusicthedriverofthecar?pages426–427vs�35m/s,v�343m/s,vd�15m/s,Level1fs�327Hz71.Averticaltubewithatapatthebaseisv�vdfilledwithwater,andatuningforkvibratesfd�fs��v��v�soveritsmouth.Asthewaterlevelislowered343�15inthetube,resonanceisheardwhenthe�(327Hz)�����350Hz343�35waterlevelhasdropped17cm,andagainafter49cmofdistanceexistsfromthewaterLevel3tothetopofthetube.Whatisthefrequency69.Atrainmovingtowardasounddetectorofthetuningfork?at31.0m/sblowsa305-Hzwhistle.What49cm�17cm�32cmor0.32mfrequencyisdetectedoneachofthe1���existsbetweenpointsofresonancefollowing?2a.astationarytrain1����0.32mv�v2f���d�d�fs�v�vs��0.64m(305Hz)(343m/s�0)f��v���343�m/s�540Hz����343m/s�31.0m/s�0.64m�335Hz72.HumanHearingTheauditorycanallead-b.atrainmovingtowardthefirsttrainatingtotheeardrumisaclosedpipethatis21.0m/s3.0cmlong.Findtheapproximatevalue(ignoringendcorrection)ofthelowestv�vf��d�d�fs�v�vresonancefrequency.s�(305Hz)(343m/s�(�21.0m/s))L��������4343m/s�31.0m/sv�356Hz���f�v343m/s70.Thetraininthepreviousproblemismov-f�������2.9kHz4L(4)(0.030m)ingawayfromthedetector.WhatfrequencyCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.isnowdetectedoneachofthefollowing?73.Ifyouholda1.2-maluminumrodinthecenterandhitoneendwithahammer,ita.astationarytrainwilloscillatelikeanopenpipe.Antinodesv�vf��d�ofpressurecorrespondtonodesofmolecu-d�fs�v�vslarmotion,sothereisapressureantinodeinthecenterofthebar.ThespeedofsoundPhysics:PrinciplesandProblemsSolutionsManual337
341Chapter15continuedinaluminumis5150m/s.Whatwouldbe78.MusicalInstrumentsThelowestnoteonthebar’slowestfrequencyofoscillation?anorganis16.4Hz.1a.WhatistheshortestopenorganpipeTherodlengthis���,so��2.4m2thatwillresonateatthisfrequency?f��v���5150�m/s�2.1kHzv343m/s�2.4m���f���16.4�Hz�20.9mand74.Onetuningforkhasa445-Hzpitch.When�L���,soasecondforkisstruck,beatnotesoccur2withafrequencyof3Hz.Whatarethetwov343m/sL�������10.5m2f(2)(16.4Hz)possiblefrequenciesofthesecondfork?b.Whatisthepitchifthesameorganpipe445Hz�3Hz�442Hzisclosed?and445Hz�3Hz�448HzSinceaclosedpipeproducesafun-75.FlutesAfluteactsasanopenpipe.Ifadamentalwithawavelengthtwiceasflutesoundsanotewitha370-Hzpitch,longasthatofanopenpipeofthewhatarethefrequenciesofthesecond,samelength,thefrequencywouldbe1third,andfourthharmonicsofthispitch?��(16.4Hz)�8.20Hz.2f2�2f1�(2)(370Hz)�740Hz79.MusicalInstrumentsTwoinstrumentsarefplayingmusicalA(440.0Hz).Abeatnote3�3f1�(3)(370Hz)�1110Hzwithafrequencyof2.5Hzisheard.�1100HzAssumingthatoneinstrumentisplayingf4�4f1�(4)(370Hz)�1480Hzthecorrectpitch,whatisthefrequencyof�1500Hzthepitchplayedbythesecondinstrument?Itcouldbeeither440.0�2.5�442.5Hz76.ClarinetsAclarinetsoundsthesamenote,or440.0�2.5�437.5Hz.withapitchof370Hz,asinthepreviousproblem.Theclarinet,however,actsasa80.Aflexible,corrugated,plastictube,shownCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.closedpipe.WhatarethefrequenciesoftheinFigure15-27,is0.85mlong.Whenitislowestthreeharmonicsproducedbythisswungaround,itcreatesatonethatistheinstrument?lowestpitchforanopenpipeofthislength.3fWhatisthefrequency?1�(3)(370Hz)�1110Hz�1100Hz0.85m5f1�(5)(370Hz)�1850Hz�1800Hz7f1�(7)(370Hz)�2590Hz�2600Hz■Figure15-27�77.StringInstrumentsAguitarstringisL�0.85m���,so��1.7m265.0cmlongandistunedtoproduceav343m/s2Hzlowestfrequencyof196Hz.f�������2.0�10�1.7ma.Whatisthespeedofthewaveonthe81.Thetubefromthepreviousproblemisstring?swungfaster,producingahigherpitch.�1�2L�(2)(0.650m)�1.30mWhatisthenewfrequency?v��f�(1.30m)(196Hz)�255m/sf2Hz)�4.0�102Hz2�2f1�(2)(2.0�10b.Whatarethenexttwohigherresonantfrequenciesforthisstring?Level2f2�2f1�(2)(196Hz)�392Hz82.Duringnormalconversation,theamplitudefofapressurewaveis0.020Pa.3�3f1�(3)(196Hz)�588Hz338SolutionsManualPhysics:PrinciplesandProblems
342Chapter15continueda.Iftheareaofaneardrumis0.52cm2,Thelengthofthesteelfingerclampedwhatistheforceontheeardrum?atoneendandfreetovibrateatthe1F�PAotheris��wavelength.Therefore,4�(0.020N/m2)(0.52�10�4m2)��4L�4(0.024m)�0.096m,and�1.0�10�6Nv�f��(1760Hz)(0.096m)b.Themechanicaladvantageofthethree�1.7�102m/sbonesinthemiddleearis1.5.IftheforceinpartaistransmittedundiminishedtoMixedReviewthebones,whatforcedothebonesexertpages427–428ontheovalwindow,themembranetoLevel1whichthethirdboneisattached?85.Anopenorganpipeis1.65mlong.WhatFMA���rsoFfundamentalfrequencynotewillitproduceFr�(MA)(Fe)eifitisplayedinheliumat0°C?F�6N)�1.5�10�6Nr�(1.5)(1.0�10Anopenpipehasalengthequaltoc.Theareaoftheovalwindowisone-halfitsfundamentalwavelength.0.026cm2.WhatisthepressureincreaseTherefore,��3.30m.Thespeedoftransmittedtotheliquidinthecochlea?soundinheliumis972m/s.Therefore,v972m/sF1.5�10�6Nf�������295HzP�������0.58Pa�3.30mA0.026�10�4m286.Ifyoudropastoneintoawellthatis83.MusicalInstrumentsOneopenorgan122.5mdeep,asillustratedinFigurepipehasalengthof836mm.Asecond15-29,howsoonafteryoudropthestoneopenpipeshouldhaveapitchthatisonewillyouhearithitthebottomofthewell?majorthirdhigher.Howlongshouldthesecondpipebe?�vL���,so��2Land����2fv343m/sf�������205Hz2L(2)(0.836m)Theratioofafrequencyonemajorthird122.5m5higheris5:4,so(205Hz)�����256Hz.4Thelengthofthesecondpipeisv343m/s2mmL�������6.70�102f(2)(256Hz)84.AsshowninFigure15-28,amusicbox■Figure15-29containsasetofsteelfingersclampedatFirstfindthetimeittakesthestonetooneendandpluckedontheotherendbyfalldowntheshaftbyd�1�gt2,so�2pinsonarotatingdrum.Whatisthespeedofawaveonafingerthatis2.4cmlongd122.5mandplaysanoteof1760Hz?t��1���1�5.00s����g������(9.80m/s2)22ThetimeittakesthesoundtocomesCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Steelfingersbackupisfoundwithd�vst,sod122.5mt�������0.357sv343m/ssThetotaltimeis5.00s�0.357s�5.36s.■Figure15-28Physics:PrinciplesandProblemsSolutionsManual339
343Chapter15continued87.Abirdonanewlydiscoveredplanetfliesfs�22.4kHz,vd�0towardasurprisedastronautataspeedofv�v1533f��d���19.5m/swhilesingingatapitchof945Hz.d�fs�v�v�(22.4kHz)�1533�4.15�sTheastronauthearsatoneof985Hz.What�22.3kHzisthespeedofsoundintheatmosphereofthisplanet?90.Whenawetfingerisrubbedaroundtherimfd�985Hz,fs�945Hz,vs�19.5m/s,ofaglass,aloudtoneoffrequency2100Hzv�?isproduced.Iftheglasshasadiameteroffdv16.2cmandthevibrationcontainsone�������fsv�vsvswavelengtharounditsrim,whatisthe1���vspeedofthewaveintheglass?vfSo��s�1���s,Thewavelengthisequaltothevfdcircumferenceoftheglassrim,���dvs19.5m/sTherefore,thespeedisorv�����fs945Hz1���1�����v��f��dff985Hzd�4.80�102m/s��(0.062m)(2100Hz)�4.1�102m/s88.InNorthAmerica,oneofthehottestout-91.HistoryofScienceIn1845,Dutchscien-doortemperatureseverrecordedis57°CtistChristophBuys-Ballotdevelopedatestandoneofthecoldestis�62°C.WhatareoftheDopplereffect.Hehadatrumpetthespeedsofsoundatthosetwotempera-playersoundanAnoteat440Hzwhiletures?ridingonaflatcarpulledbyalocomotive.Atthesametime,astationarytrumpeterv(T)�v(0°C)�(0.6m/s)T,whereplayedthesamenote.Buys-Ballotheardv(0°C)�331m/s.So,v(57°C)3.0beatspersecond.Howfastwasthetrain0.6m/smovingtowardhim?�(331m/s)�����(57°C)°Cfd�440Hz�3.0Hz�443HzCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�365m/s0.6m/sv�vdv(�62°C)�(331m/s)���°C��(�62°C)fd�fs����v�vs�294m/sso(v�vs)fd�(v�vd)fsand(v�vLevel2v��d)fss�v�f89.Aship’ssonarusesafrequencyof22.5kHz.dThespeedofsoundinseawateris1533m/s.(343m/s�0)(440Hz)�343m/s����Whatisthefrequencyreceivedontheship443Hzthatwasreflectedfromawhaletravelingat�2.3m/s4.15m/sawayfromtheship?Assumethattheshipisatrest.92.YoutrytorepeatBuys-Ballot’sexperimentPart1.Fromshiptowhale:fromthepreviousproblem.Youplantohaveatrumpetplayedinarapidlymovingvd��4.15m/s,v�1533m/s,car.Ratherthanlisteningforbeatnotes,fs�22.5kHz,vs�0however,youwanttohavethecarmovefastv�vd1533�4.15enoughsothatthemovingtrumpetsoundsfd�fs��v��v��(22.5kHz)����s1533onemajorthirdaboveastationarytrumpet.�22.4kHza.Howfastwouldthecarhavetomove?Part2.Fromwhaletoship:5majorthirdratio���v4s��4.15m/s,v�1533m/s,340SolutionsManualPhysics:PrinciplesandProblems
344Chapter15continuedv�vd�367Hzfd�fs��v��v�sPart2.vd��37.5m/s,v�343m/s,so(v�vs)fd�(v�vd)fsfs�367Hz(v�vd)fsv�vd343�(�37.5)andvs�v��f�fd�fs��v��v��(367Hz)��34�3�ds4�343m/s�(343m/s�0)��5���407Hz�68.6m/sb.Shouldyoutrytheexperiment?Explain.ThinkingCritically3600s1mipage428v�(68.6m/s)��������95.MakeandUseGraphsThewavelengthsof1h1609m�153mph,thesoundwavesproducedbyasetoftun-ingforkswithgivenfrequenciesareshownsothecarwouldbemovinginTable15-2below.dangerouslyfast.Donottrytheexperiment.Table15-2TuningForksLevel3Frequency(Hz)Wavelength(m)93.GuitarStringsTheequationforthespeed1312.62Fofawaveonastringisv���T,whereF���Tis1472.33thetensioninthestringand�isthemass1652.08perunitlengthofthestring.Aguitarstring1961.75hasamassof3.2gandis65cmlong.2201.56Whatmustbethetensioninthestring2471.39toproduceanotewhosefundamentalfrequencyis147Hz?a.Plotagraphofthewavelengthversus��0.003�2kg�4.9�10�3kg/mthefrequency(controlledvariable).�0.65mWhattypeofrelationshipdoesthe��2L�2(0.65m)�1.30mgraphshow?v�f��(147Hz)(1.30m)�191m/sThegraphshowsaninverserela-F2��(191m/s)2(4.9�10�3kg/m)tionshipbetweenfrequencyandT�vwavelength.�180N94.Atrainspeedingtowardatunnelat2.6037.5m/ssoundsitshornat327Hz.Thesoundbouncesoffthetunnelmouth.What2.20isthefrequencyofthereflectedsoundheardonthetrain?Hint:Solvetheproblem(m)�1.80intwoparts.First,assumethatthetunnelisastationaryobserverandfindthe1.40frequency.Then,assumethatthetunnelisastationarysourceandfindthefrequency1.00Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.measuredonthetrain.100140180240260Part1.vs��37.5m/s,v�343m/s,f(Hz)fs�327Hzb.Plotagraphofthewavelengthversusf�v��vd��(327Hz)��343��theinverseofthefrequency(1/f).Whatd�fs�v�v343�37.5skindofgraphisthis?DeterminethePhysics:PrinciplesandProblemsSolutionsManual341
345Chapter15continuedspeedofsoundfromthisgraph.frequencythanlightfromtherightside.ThegraphshowsadirectrelationshipWhatdothesemeasurementstellyouaboutbetweenperiod(1/f)andwavelength.theSun’smotion?ThespeedofsoundisrepresentedTheSunmustberotatingonitsaxisinbytheslope,~343m/s.thesamemannerasEarth.TheDopplershiftindicatesthattheleftsideofthe2.60Suniscomingtowardus,whiletherightsideismovingaway.2.2099.DesignanExperimentDesignanexperi-(m)mentthatcouldtesttheformulaforthe�1.80speedofawaveonastring.Explainwhatmeasurementsyouwouldmake,howyou1.40wouldmakethem,andhowyouwouldusethemtotesttheformula.1.00Measurethemassandlengthofthe4.06.08.01stringtodetermine�.Thenclampthe–(ms)fstringtoatable,hangoneendoverthe96.MakeGraphsSupposethatthefrequencytableedge,andstretchthestringbyofacarhornis300Hzwhenitisstation-hangingweightsonitsendtoobtainFT.ary.WhatwouldthegraphofthefrequencyCalculatethespeedofthewaveusingversustimelooklikeasthecarapproachedtheformula.Next,pluckthestringinitsandthenmovedpastyou?Completeamiddleanddeterminethefrequencybyroughsketch.matchingittoafrequencygenerator,usingbeatstotunethegenerator.ThegraphshouldshowafairlysteadyMultiplythefrequencybytwicethestringfrequencyabove300Hzasitapproach-length,whichisequaltothewavelength,esandafairlysteadyfrequencybelowtoobtainthespeedfromthewaveequa-300Hzasitmovesaway.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tion.Comparetheresults.Repeatfordif-97.AnalyzeandConcludeDescribehowyouferenttensionsandotherstringswithcoulduseastopwatchtoestimatethespeeddifferentmassesperunitlength.ofsoundifyouwerenearthegreenona200-Considerpossiblecausesoferror.mgolfholeasanothergroupofgolfershittheirteeshots.WouldyourestimateoftheWritinginPhysicsspeedofsoundbetoolargeortoosmall?page428Youcouldstartthewatchwhenyou100.Researchtheconstructionofamusicalsawthehitandstopthewatchwheninstrument,suchasaviolinorFrenchthesoundreachedyou.Thespeedhorn.Whatfactorsmustbeconsideredwouldbecalculatedbydividingthedis-besidesthelengthofthestringsortube?tance,200m,bythemeasuredtime.TheWhatisthedifferencebetweenaqualitymeasuredtimewouldbetoolargeinstrumentandacheaperone?Howarebecauseyoucouldanticipatethetheytestedfortonequality?impactbysight,butyoucouldnotAnswerswillvary.Areportonviolinanticipatethesound.Thecalculatedconstructionmightincludeinformationspeedwouldbetoosmall.aboutthebridgeasalinkbetweenthestringsandbodyandinformation98.ApplyConceptsAlightwavecomingfromabouttheroleofthebodyincausingapointontheleftedgeoftheSunisfoundairmoleculesaroundtheviolintobyastronomerstohaveaslightlyhighervibrate.Studentsalsomightdiscuss342SolutionsManualPhysics:PrinciplesandProblems
346Chapter15continuedthewaysinwhichthewoodsandfin-b.CalculatethemomentumandvelocityishesusedinmakingviolinsaffecttheofballBafterthecollision.qualityofthesoundproducedbytheHorizontal:mAvA1�mBvB2instruments.SomBvB2�(1.0kg)(3.0m/s)101.ResearchtheuseoftheDopplereffectin�3.0kg�m/sthestudyofastronomy.WhatisitsroleinVertical:0�mthebigbangtheory?HowisitusedtoAvA2�mBvB2detectplanetsaroundotherstars?TostudySomBvB2��(1.0kg)(2.0m/s)themotionsofgalaxies?��2.0kg�m/sStudentsshoulddiscusstheworkofThevectorsumisEdwinHubble,theredshiftandthemexpandinguniverse,spectroscopy,andvthedetectionofwobblesinthemotion��(3.0k�g��m/s)�2�(��2.0kg��m/�s)2ofplanet-starsystems.2.0kg�m/s�3.6kg�m/sandtan����3.0kg�m/sCumulativeReviewso��34°page428Therefore,mBvB2�3.6kg�m/sat102.BallA,rollingwestat3.0m/s,hasamassof1.0kg.BallBhasamassof2.0kgand34°northofwestisstationary.AftercollidingwithballB,3.6kg�m/sv��ballAmovessouthat2.0m/s.(Chapter9)B2�2.0kga.Sketchthesystem,showingtheveloci-�1.8m/sat34°northofwesttiesandmomentabeforeandafterthecollision.103.Chriscarriesa10-Ncartonofmilkalongalevelhalltothekitchen,adistanceofWestwardandsouthwardare3.5m.HowmuchworkdoesChrisdo?positive.(Chapter10)BeforeBANowork,becausetheforceandthedisplacementareperpendicular.pB1=0vA1=3.0m/swest104.Amoviestuntpersonjumpsfromafive-pA1=3.0kg�m/sweststorybuilding(22mhigh)ontoalargeAfterpillowatgroundlevel.Thepillowcush-Aionsherfallsothatshefeelsadecelerationofnomorethan3.0m/s2.Ifsheweighs480N,howmuchenergydoesthepillow�havetoabsorb?Howmuchforcedoesthepillowexertonher?(Chapter11)TheenergytobeabsorbedequalstheAmechanicalenergythatshehad,whichequalsherinitialpotentialenergy.U�mgh�(480N)(22m)�11kJ.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.TheforceonherisvB2=?Fg480Np=?F�ma���(a)����2�(3.0m/s2)B2g9.80m/svA2=2.0m/ssouthpA2=2.0kg�m/ssouth�150NPhysics:PrinciplesandProblemsSolutionsManual343
347Chapter15continuedChallengeProblempage4171.Determinethetension,FT,inaviolinstringofmassmandlengthLthatwillplaythefundamentalnoteatthesamefrequencyasaclosedpipealsooflengthL.Expressyouranswerintermsofm,L,andthespeedofsoundinFair,v.Theequationforthespeedofawaveonastringisu���T.whereF���Tisthetensionstringand�isthemassperunitlengthofthestring.Thewavelengthofthefundamentalinaclosedpipeisequalto4L,sovthefrequencyisf���.Thewavelengthofthefundamentalonastringis4Luequalto2L,sothefrequencyofthestringisf���,whereuisthespeed2LFofthewaveonthestring,u�����T.Themassperunitlengthofthestring���m/L.Squaringthefrequenciesandsettingthemequalgivesv2u2FTFTLFT�16�L2��4L�2��4L�2���4L2�m��4L�mmv2Finally,rearrangingforthetensiongivesF��T�4L2.Whatisthetensioninastringofmass1.0gand40.0cmlongthatplaysthesamenoteasaclosedpipeofthesamelength?Forastringofmass1.0gandlength0.400m,thetensionismv2(0.0010kg)(343m/s)2F�������74NT�4L4(0.400m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.344SolutionsManualPhysics:PrinciplesandProblems
348CHAPTER16FundamentalsofLight4.A64-cdpointsourceoflightis3.0mabovePracticeProblemsthesurfaceofadesk.Whatistheillumina-16.1Illuminationtiononthedesk’ssurfaceinlux?pages431–438P�4�(64cd)�256�lmpage436P256�lmsoE������7.1lx1.Alampismovedfrom30cmto90cm4�d24�(3.0m)2abovethepagesofabook.Comparethe5.Apublicschoollawrequiresaminimumilluminationonthebookbeforeandafterilluminanceof160lxatthesurfaceofeachthelampismoved.student’sdesk.Anarchitect’sspecificationsPE��4�d�2�d2callforclassroomlightstobelocated2.0m�after���after�beforeEPd2abovethedesks.Whatistheminimumbefore����afterluminousfluxthatthelightsmustproduce?4�d2beforeP(30cm)21E��2�����;therefore,after4�d(90cm)29P�4�Ed2thelampismovedtheilluminationisone-ninthoftheoriginalillumination.�4�(160lm/m2)(2.0m)22.Whatistheilluminationonasurfacethatis�8.0�103lm3.0mbelowa150-Wincandescentlampthatemitsaluminousfluxof2275lm?6.Ascreenisplacedbetweentwolampssothattheyilluminatethescreenequally,asP2275lm1lxE���4�d2��4�(3.0m)2�2.0�10showninFigure16-7.Thefirstlampemitsaluminousfluxof1445lmandis2.5m3.Drawagraphoftheilluminanceproducedfromthescreen.Whatisthedistanceofbya150-Wincandescentlampbetweenthesecondlampfromthescreenifthe0.50mand5.0m.luminousfluxis2375lm?Illuminanceofa150-WbulbScreenP�2275,d�0.50,0.75,…,5.0PE(d)��4�d2P�2375lm2.5m720P�1445lm■Figure16-7(Nottoscale)(lx)EP�2275lmE1�E2PPSo�1��2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.7.2d2d2120.505.0Pr(m)ord��22�d1��P12375�(2.5m)���1445�3.2mPhysics:PrinciplesandProblemsSolutionsManual345
349Chapter16continuedd2SectionReview�f��1(1.0m)2216.1Illumination1d�pages431–438f���2mpage438�0.71m7.UseofMaterialLightPropertiesWhymightyouchooseawindowshadethatis11.DistanceofLightTravelHowfardoestranslucent?Opaque?lighttravelinthetimeittakessoundtoYouwoulduseatranslucentwindowtravel1cminairat20°C?shadetokeeppeoplefromlookinginorSoundvelocityis343m/s,sosoundout,whilestillallowingdaylightin.Youtakes3�10�5stotravel1cm.Inthatwoulduseanopaquewindowshadetotime,lighttravels9km.keepthedaylightout.vsound�343m/s8.IlluminanceDoesonelightbulbprovidedt�sound�vmoreilluminancethantwoidenticallight-soundbulbsattwicethedistance?Explain.1�10�2m���Onelightbulbprovidesanilluminance343m/sthatisfourtimeslargerthantwoofthe�3�10�5ssamelightbulbattwicethedistance,Pv8m/sbecauseE��.light�3.00�10d2dlight�vlighttsound9.LuminousIntensityTwolampsilluminate�(3.00�108m/s)(3�10�5s)ascreenequally—lampAat5.0m,lampBat3.0m.IflampAisrated75cd,whatis�9�103m�9kmlampBrated?12.DistanceofLightTravelThedistancetoIE��2theMooncanbefoundwiththehelpofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.dmirrorsleftontheMoonbyastronauts.ASincetheilluminationisequal,pulseoflightissenttotheMoonandE1�E2returnstoEarthin2.562s.UsingtheIImeasuredvalueofthespeedoflighttotheSo�1��2d2d2sameprecision,calculatethedistancefrom12EarthtotheMoon.I2orI�1d22�d2d�ct11(75cd)(3.0m)2�(299,800,000m/s)���2(2.562s)����27cd(5.0m)2�3.840�108m10.DistanceofaLightSourceSupposethat13.CriticalThinkingUsethecorrecttimealightbulbilluminatingyourdeskprovidestakenforlighttocrossEarth’sorbit,onlyhalftheilluminancethatitshould.If16.5min,andthediameterofEarth’sorbit,itiscurrently1.0maway,howfarshouldit2.98�1011m,tocalculatethespeedoflightbetoprovidethecorrectilluminance?usingRoemer’smethod.DoesthismethodIlluminationdependson1/d2,appeartobeaccurate?Whyorwhynot?Ed21so�i���f�d3.0�1011Efd22v������it(16min)(60s/min)�3.1�108m/s346SolutionsManualPhysics:PrinciplesandProblems
350Chapter16continuedPracticeProblems(��vobs��)��c�16.2TheWaveNaturev��ofLightobs���1�c�pages439–447�7m)6.55�106�(4.86�10�1���3.00�108m/spage447���m/s14.Whatisthefrequencyofoxygen’sspectrallineifitswavelengthis513nm?�4.97�10�7mcUse���fandsolveforf.17.Anastronomerislookingatthespectrumofagalaxyandfindsthatithasanoxygencf��spectrallineof525nm,whilethelaboratory�valueismeasuredat513nm.Calculatehow3.00�108m/s���5.13�10�7mfastthegalaxywouldbemovingrelativetoEarth.Explainwhetherthegalaxyismoving�5.85�1014HztowardorawayfromEarthandhowyouknow.15.Ahydrogenatominagalaxymovingwith6m/sawayfromAssumethattherelativespeedalongaspeedof6.55�10theaxisismuchlessthanthespeedofEarthemitslightwithafrequencyof14Hz.Whatfrequencyoflightlight.Thus,youcanusetheDoppler6.16�10shiftequation.fromthathydrogenatomwouldbeobservedbyanastronomeronEarth?(��vobs��)��c�TherelativespeedalongtheaxisismuchTheobserved(apparent)wavelengthlessthanthespeedoflight.Thus,youappearstobelongerthantheknowncanusetheobservedlightfrequency(actual)wavelengthoftheoxygenequation.Becausetheastronomerandspectralline.Thismeansthatthethegalaxyaremovingawayfromeachastronomerandthegalaxyaremovingother,usethenegativeformoftheawayfromeachother.Sousetheposi-observedlightfrequencyequation.tiveformoftheDopplershiftequation.vfobs�f�1��c�v(��obs��)��c�14Hz)6.55�106m/s�(6.16�10�1���3.00�1�08m/s��Solvefortheunknownvariable.�6.03�1014Hz(�obs��)v�c���16.Ahydrogenatominagalaxymovingwith8m/s)(525nm�513nm)16m/sawayfrom�(3.00�10�����513nmaspeedof6.55�10Earthemitslightwithawavelengthof�7.02�106m/s4.86�10�7m.WhatwavelengthwouldbeobservedonEarthfromthathydrogenatom?Therelativespeedalongtheaxisismuchlessthanthespeedoflight.Thus,youcanusetheobservedDopplershiftCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.equation.Becausetheastronomerandthegalaxyaremovingawayfromeachother,usethepositiveformoftheDopplershiftequation.Physics:PrinciplesandProblemsSolutionsManual347
351Chapter16continued22.PolarizationDescribeasimpleexperimentSectionReviewthatyoucoulddotodeterminewhether16.2TheWaveNaturesunglassesinastorearepolarizing.ofLightSeeiftheglassesreduceglarefromthepages439–447reflectivesurfaces,suchaswindowsorroadways.Polarizationoflightallowspage447photographerstophotographobjects18.AdditionofLightColorsWhatcolorofwhileeliminatingglare.lightmustbecombinedwithbluelighttoobtainwhitelight?23.CriticalThinkingAstronomershavedeter-yellow(amixtureoftheothertwopri-minedthatAndromeda,aneighboringmaries,redandgreen)galaxytoourowngalaxy,theMilkyWay,ismovingtowardtheMilkyWay.Explainhow19.CombinationofPigmentsWhatprimarytheydeterminedthis.CanyouthinkofapigmentcolorsmustbemixedtoproducepossiblereasonwhyAndromedaismovingred?Explainhowredresultsusingcolortowardourgalaxy?subtractionforpigmentcolors.ThespectrallinesoftheemissionsofYellowandmagentapigmentsareusedknownatomsareblue-shiftedinthetoproducered.Yellowpigmentsub-lightweseecomingfromAndromeda.tractsblueandmagentapigmentsub-Andromedawouldbemovingtowardustractsgreen,neithersubtractsredsoduetogravitationalattraction.Thisthemixturewouldreflectred.gravitationalattractioncouldbeduetothemassoftheMilkyWayorother20.LightandPigmentInteractionWhatobjectslocatedneartheMilkyWay.colorwillayellowbananaappeartobewhenilluminatedbyeachofthefollowing?a.whitelightChapterAssessmentyellowConceptMappingCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.greenandredlightpage452yellow24.Completethefollowingconceptmapusingc.bluelightthefollowingterms:wave,c,Dopplereffect,blackpolarization.21.WavePropertiesofLightThespeedofLightModelsredlightisslowerinairandwaterthaninavacuum.Thefrequency,however,doesnotchangewhenredlightenterswater.Doesthewavelengthchange?Ifso,how?raywaveYes,becausev��fand��v/f,whenvdecreases,sodoes�.straightDopplerdiffractionceffectpathpolarization�0�c/f348SolutionsManualPhysics:PrinciplesandProblems
352Chapter16continuedMasteringConcepts31.WhatdidGalileoassumeaboutthespeedoflight?(16.1)page45225.Sounddoesnottravelthroughavacuum.Thespeedoflightisveryfast,butfinite.Howdoweknowthatlightdoes?(16.1)32.WhyisthediffractionofsoundwavesmoreLightcomesthroughthevacuumoffamiliarineverydayexperiencethanisthespacefromtheSun.diffractionoflightwaves?(16.2)26.DistinguishbetweenaluminoussourceandDiffractionismostpronouncedaroundanilluminatedsource.(16.1)obstaclesapproximatelythesamesizeasthewavelengthofthewave.WeareAluminousbodyemitslight.Anillumi-moreaccustomedtoobstaclesofthenatedbodyisoneonwhichlightfallssizethatdiffractthemuchlargerwave-andisreflected.lengthsofsound.27.Lookcarefullyatanordinary,frosted,33.Whatcoloroflighthastheshortestincandescentbulb.Isitaluminousoranwavelength?(16.2)illuminatedsource?(16.1)Violetlighthastheshortestwave-Itismainlyilluminated.Thefilamentlength.isluminous;thefrostedglassisillumi-nated.Youbarelycanseethehot34.Whatistherangeofthewavelengthsoffilamentthroughthefrostedglass.light,fromshortesttolongest?(16.2)28.Explainhowyoucanseeordinary,nonlu-400nmto700nmminousclassroomobjects.(16.1)35.Ofwhatcolorsdoeswhitelightconsist?Ordinarynonluminousobjectsareillu-(16.2)minatedbyreflectedlight,allowingWhitelightisacombinationofallthethemtobeseen.colors,oratleasttheprimarycolors.29.Distinguishamongtransparent,translucent,36.Whydoesanobjectappeartobeblack?andopaqueobjects.(16.1)(16.2)AtransparentobjectisamaterialAnobjectappearstobeblackbecausethroughwhichlightcanpasswithoutlittle,ifany,lightisbeingreflecteddistortion.Atranslucentobjectallowsfromit.lighttopassbutdistortsthelighttothepointwhereimagesarenotdiscernable.37.Canlongitudinalwavesbepolarized?AnopaqueobjectdoesnotallowlightExplain.(16.2)topassthrough.No.Theyhavenoverticalorhorizontal30.Towhatistheilluminationofasurfacebyacomponents.lightsourcedirectlyproportional?Towhatisitinverselyproportional?(16.1)38.Ifadistantgalaxyweretoemitaspectrallineinthegreenregionofthelightspec-Theilluminationonasurfaceisdirectlytrum,wouldtheobservedwavelengthonproportionaltotheintensityoftheEarthshifttowardredlightortowardbluesourceandinverselyproportionaltotheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.light?Explain.(16.2)squareofthedistanceofthesurfacefromthesource.Becausethegalaxyisdistant,itismostlikelymovingawayfromEarth.Thewavelengthactuallywouldshiftawayfromthewavelengthofgreenlighttowardalongerredwavelength.IfitPhysics:PrinciplesandProblemsSolutionsManual349
353Chapter16continuedshiftedtowardthebluewavelength,theobservingorphotographingobjects.wavelengthwouldbeshorter,notlonger.Thiswouldindicatethegalaxyis43.EyeSensitivityTheeyeismostsensitivetogettingclosertoEarth,andnogalaxyyellow-greenlight.ItssensitivitytoredandoutsidetheLocalGrouphasbeendis-bluelightislessthan10percentasgreat.coveredmovingtowardus.Basedonthisknowledge,whatcolorwouldyourecommendthatfiretrucksandambu-39.Whathappenstothewavelengthoflightaslancesbepainted?Why?thefrequencyincreases?(16.2)Firetrucksshouldbepaintedyellow-Asthefrequencyincreases,thewave-green,550nm,becauselesslighthastolengthdecreases.bereflectedtotheeyeforthefiretrucktobeseen.ApplyingConcepts44.StreetlightColorSomeveryefficientpage452streetlightscontainsodiumvaporunder40.Apointsourceoflightis2.0mfromscreenhighpressure.TheyproducelightthatisAand4.0mfromscreenB,asshowninmainlyyellowwithsomered.ShouldaFigure16-21.HowdoestheilluminanceatcommunitythathastheselightsbuydarkscreenBcomparewiththeilluminanceatbluepolicecars?Whyorwhynot?screenA?BluepigmentofapolicecarwillabsorbScreenAScreenBtheredandyellowlight.Darkbluepolicecarswouldnotbeveryvisible.IfSourceacommunitywantsitspolicecarstobevisible,theyshouldbuyyellowcars.2m4mRefertoFigure16-22forproblems45and46.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.■Figure16-21IlluminationE�l/r2;therefore,theillu-minationatscreenBwillbeone-fourthofthatatscreenAbecauseitistwiceasfarfromthesource.■Figure16-2241.ReadingLampYouhaveasmallreadinglampthatis35cmfromthepagesofa45.Whathappenstotheilluminanceatabook.Youdecidetodoublethedistance.bookasthelampismovedfartherawaya.Istheilluminanceatthebookthesame?fromthebook?No.Illuminancedecreases,asdescribedbyb.Ifnot,howmuchmoreorlessisit?theinverse-squarelaw.Distanceisdoubled,sotheillumina-46.Whathappenstotheluminousintensityoftionofthepageisone-fourthasthelampasitismovedfartherawayfromgreat.thebook?42.WhyaretheinsidesofbinocularsandNochange;distancedoesnotaffectthecameraspaintedblack?luminousintensityofthelamp.Theinsidesarepaintedblackbecauseblackdoesnotreflectanylight,andthusthereisnointerferencewhile350SolutionsManualPhysics:PrinciplesandProblems
354Chapter16continued47.PolarizedPicturesPhotographersoften52.TrafficViolationSupposethatyouareaputpolarizingfiltersovercameralensestotrafficofficerandyoustopadriverformakecloudsintheskymorevisible.Thegoingthrougharedlight.Furthersupposecloudsremainwhite,whiletheskylooksthatthedriverdrawsapictureforyoudarker.Explainthisbasedonyourknowl-(Figure16-23)andexplainsthatthelightedgeofpolarizedlight.lookedgreenbecauseoftheDopplereffectLightscatteredfromtheatmosphereiswhenhewentthroughit.Explaintohimpolarized,butlightscatteredfromtheusingtheDopplershiftequationjusthowcloudsisnot.Byrotatingthefilter,thefasthewouldhavehadtobegoingforthephotographercanreducetheamountofredlight(��645nm),toappeargreen(��polarizedlightreachingthefilm.545nm).Hint:Forthepurposeofthisprob-lem,assumethattheDopplershiftequationis48.Anappleisredbecauseitreflectsredlightvalidatthisspeed.andabsorbsblueandgreenlight.a.Whydoesredcellophanelookredinreflectedlight?Cellophanereflectsredlightandabsorbsblueandgreenlight.b.Whydoesredcellophanemakeawhitelightbulblookredwhenyouholdthe■Figure16-23cellophanebetweenyoureyeandthelightbulb?�����645nm�545nm(3.00�108m/s)�Cellophanetransmitsredlight.645nm4.65�107m/sc.Whathappenstotheblueandgreenlight?Thatisover100millionmph.IfhedoesBlueandgreenlightareabsorbed.notgetaticketforrunningaredlight,hewillgetaticketforspeeding.49.YouputapieceofredcellophaneoveroneflashlightandapieceofgreencellophaneMasteringProblemsoveranother.Youshinethelightbeamson16.1Illuminationawhitewall.Whatcolorwillyouseewherepage453thetwoflashlightbeamsoverlap?Level1yellow53.Findtheillumination4.0mbelowa405-lmlamp.50.Younowputboththeredandgreencello-P405lmphanepiecesoveroneoftheflashlightsinE���2�4�(4.0�m)2�2.0lx4�dProblem49.Ifyoushinetheflashlightbeamonawhitewall,whatcolorwillyou54.Lighttakes1.28stotravelfromtheMoontosee?Explain.Earth.Whatisthedistancebetweenthem?Black;almostnolightwouldgetd�vt�(3.00�108m/s)(1.28s)throughbecausethelighttransmitted�3.84�108mthroughthefirstfilterwouldbeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.absorbedbythesecond.Level255.Athree-waybulbuses50,100,or150W51.Ifyouhaveyellow,cyan,andmagentapig-ofelectricpowertodeliver665,1620,orments,howcanyoumakeabluepigment?2285lminitsthreesettings.ThebulbisExplain.placed80cmaboveasheetofpaper.IfanMixcyanandmagenta.Physics:PrinciplesandProblemsSolutionsManual351
355Chapter16continuedilluminationofatleast175lxisneededonPPSo�1��2thepaper,whatistheminimumsettingthatd2d212shouldbeused?P2orP��1d2E��P2�d24�d21P�4�Ed2�4�(175lx)(0.80m)2(1750lm)(1.08m)2����(1.25m)2�1.4�103lm�1.31�103lmThus,the100-W(1620-lm)settingisneeded.58.Supposethatyouwantedtomeasurethespeedoflightbyputtingamirroronadis-56.Earth’sSpeedOleRoemerfoundthatthetantmountain,settingoffacameraflash,averageincreaseddelayinthedisappear-andmeasuringthetimeittakestheflashtoanceofIofromoneorbitaroundJupitertoreflectoffthemirrorandreturntoyou,asthenextis13s.showninFigure16-24.Withoutinstru-a.Howfardoeslighttravelin13s?ments,apersoncandetectatimeintervalof3.9�109mabout0.10s.Howmanykilometersawaywouldthemirrorhavetobe?Comparethisb.EachorbitofIotakes42.5h.Earthtrav-distancewiththatofsomeknowndistances.elsthedistancecalculatedinpartain42.5h.FindthespeedofEarthinkm/s.dMirrorYouv��td3.9�109m1km�����5s��1000m�1.53�10�25km/sc.Checktomakesurethatyouranswerforpartbisreasonable.CalculateEarth’sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.speedinorbitusingtheorbitalradius,1.5�108km,andtheperiod,1.0yr.■Figure16-24d2�(1.5�108km)1dv����������d�vtt365d24h1h8m/s)(0.1s)1km����(3.00�10���1000m3600s�3.0�101km/s,sofairlyaccurate�3�104kmThemirrorwouldbehalfthisdistance,Level3or15,000kmaway.Earthis40,000km57.Astudentwantstocomparetheluminousincircumference,sothisisthree-fluxofalightbulbwiththatofa1750-lmeighthsofthewayaroundEarth.lamp.Thelightbulbandthelampillumi-nateasheetofpaperequally.The1750-lmlampis1.25mawayfromthesheetof16.2TheWaveNatureofLightpaper;thelightbulbis1.08maway.Whatpages453–454isthelightbulb’sluminousflux?Level1P59.Convert700nm,thewavelengthofredE��4�d2light,tometers.Sincetheilluminationisequal,1�10�9m�7m(700nm)�����7�101nmE1�E2352SolutionsManualPhysics:PrinciplesandProblems
356Chapter16continued60.GalacticMotionHowfastisagalaxymov-Level2ingrelativetoEarthifahydrogenspectral62.PolarizingSunglassesInwhichdirectionlineof486nmisred-shiftedto491nm?shouldthetransmissionaxisofpolarizingAssumethattherelativespeedalongsunglassesbeorientedtocuttheglarefromtheaxisismuchlessthanthespeedofthesurfaceofaroad:verticallyorhorizon-light.Thus,youcanusetheDopplertally?Explain.shiftequation.Thetransmissionaxisshouldbevorientedvertically,sincethelight(��app��)��c�reflectingofftheroadwillbepartiallyThelightisred-shifted,sotheastron-polarizedinthehorizontaldirection.omerandthegalaxyaremovingawayAverticaltransmissionaxiswillfilterfromeachother.Sousethepositivehorizontalwaves.formoftheapparentlightwavelength63.GalacticMotionAhydrogenspectrallineequation.thatisknowntobe434nmisred-shiftedv(�app��)���c�by6.50percentinlightcomingfromadis-tantgalaxy.HowfastisthegalaxymovingSolvefortheunknownvariable.awayfromEarth?(�app��)Assumethattherelativespeedalongv�c���theaxisismuchlessthanthespeedof8m/s)491nm�486nmlight.Thus,youcanusetheDoppler�(3.00�10�����486nmshiftequation.�3.09�106m/sv(��app��)��c�Theoriginalassumptionwasvalid.Thelightisred-shifted,sotheastron-61.Supposethatyouarefacingdueeastatsun-omerandthegalaxyaremovingawayrise.Sunlightisreflectedoffthesurfaceofafromeachother.Sousethepositivelake,asshowninFigure16-25.Istheformoftheapparentlightwavelengthreflectedlightpolarized?Ifso,inwhatequation.direction?v(��app��)��c�Solvefortheunknownvariable.(�app��)v�c����(3.00�108m/s)(1.065)(434nm)�434nm������434nm�1.95�107m/sTheoriginalassumptionwasvalid.■Figure16-25ThereflectedlightispartiallypolarizedLevel3inthedirectionparalleltothesurfaceof64.Foranyspectralline,whatwouldbeanthelakeandperpendiculartothepathCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.unrealisticvalueoftheapparentwavelengthoftravelofthelightfromthelaketoforagalaxymovingawayfromEarth?Why?youreyes.Anunrealisticvaluewouldmakethegalaxyseemtobemovingawayfromusataspeedclosetoorgreaterthanthespeedoflight,orv�c.IfthiswerethePhysics:PrinciplesandProblemsSolutionsManual353
357Chapter16continuedcase,useofthelow-speedDopplershiftilluminatedandequationwouldgiveawavelengthE1�E2cdifferenceof(��app��)��c�.WhenI1I2So���solved,thiswouldgiveanapparentd2d212wavelengthof�app�2�.ItwouldbeI60.0cdtwiceaslargeastheactualwavelength.ord�2��(6.0m)��2�d1��I��10.0c�d1Soanyapparentwavelengthclosetoorgreaterthantwicetheactualwave-�15mlengthwouldbeunrealistic.68.ThunderandLightningExplainwhyitMixedReviewtakes5stohearthunderwhenlightningis1.6kmaway.page454Thetimeforlighttotravel1.6kmisaLevel1smallfractionofasecond(5.3�s).The65.StreetlightIlluminationAstreetlightsoundtravelsabout340m/s,whichiscontainstwoidenticalbulbsthatare3.3maboutone-fifthofthe1.6kmeveryabovetheground.Ifthecommunitywantssecond,andtakesabout4.7stotraveltosaveelectricalenergybyremovingone1.6km.bulb,howfarfromthegroundshouldthestreetlightbepositionedtohavethesameLevel3illuminationonthegroundunderthelamp?69.SolarRotationBecausetheSunrotatesonPE��itsaxis,oneedgeoftheSunmovestoward4�d2Earthandtheothermovesaway.TheSunIfPisreducedbyafactorof2,sorotatesapproximatelyonceevery25days,mustd2.andthediameteroftheSunis1.4�109m.Thus,disreducedbyafactorof�2�,HydrogenontheSunemitslightoffre-becomingquency6.16�1014Hzfromthetwosidesof(3.3m)theSun.WhatchangesinwavelengthareCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��2.3mobserved?�2�Speedofrotationisequaltocircumfer-66.Anoctaveinmusicisadoublingoffre-encetimesperiodofrotation.quency.Comparethenumberofoctaves(1.4�109m)�v����thatcorrespondtothehumanhearingrot�(25days)(24h/day)(3600s/h)rangetothenumberofoctavesinthe�2.04�103m/shumanvisionrange.cHumanshearoverarangeofabout���fnineortenoctaves(20Hzto10,240or3.00�108m/s20,480Hz);however,humanvisionis���6.16�1014Hzlessthanone“octave.”�4.87�10�7mLevel2v������67.A10.0-cdpoint-sourcelampanda60.0-cdcpoint-sourcelampcastequalintensitiesonvrot������awall.Ifthe10.0-cdlampis6.0mfromthecwall,howfarfromthewallisthe60.0-cd(2.04�103m/s)�7m)����(4.87�10lamp?(3.00�108m/s)E��Iandsincetheintensitiesonthe��3.3�10�12md2wallareequal,thewallisequally354SolutionsManualPhysics:PrinciplesandProblems
358Chapter16continuedThinkingCritically74.LookupinformationontheSIunitcandela,cd,andexplaininyourownpage454wordsthestandardthatisusedtoset70.ResearchWhydidGalileo’smethodforthevalueof1cd.measuringthespeedoflightnotwork?Answerswillvary.Beginwiththeele-Itwasnotpreciseenough.Hewasnotmentthorium.Heatittothemeltingabletomeasurethesmalltimeintervalspointofplatinum.Atthistemperature,involvedinaterrestrialmeasurement.thethoriumwillglow.Surroundthetho-71.MakeandUseGraphsA110-cdlightriumwithanopaquematerialthatcansourceis1.0mfromascreen.Determinetakethehightemperature.Leaveantheilluminationonthescreenoriginallyopeningthatisone-sixtiethofasquareandforeverymeterofincreasingdistancecentimeterinsize.Thecandelaisupto7.0m.Graphthedata.definedastheamountofsteadyflowoflightenergythatisemittedbythe110thoriumthroughtheopeningunder100theseconditions.908070CumulativeReview60P�1.4�103lm(lm)page454E504075.A2.0-kgobjectisattachedtoa1.5-mlong30stringandswunginaverticalcircleata20constantspeedof12m/s.(Chapter7)10a.Whatisthetensioninthestringwhen0.01.02.03.04.05.06.07.0theobjectisatthebottomofitspath?r(m)mv2(2.0kg)(12m/s)2a.Whatistheshapeofthegraph?F���net��r1.5mhyperbola�1.9�101Nb.Whatistherelationshipbetweenillumi-nanceanddistanceshownbythegraph?F2)g�mg�(2.0kg)(9.80m/sinversesquare�2.0�102N72.AnalyzeandConcludeIfyouweretoFnet�T�FgdriveatsunsetinacityfilledwithbuildingsT�Fnet�Fgthathaveglass-coveredwalls,thesettingSunreflectedoffthebuilding’swallsmight�1.9�102N�0.20�102Ntemporarilyblindyou.Wouldpolarizing�2.1�102Nglassessolvethisproblem?b.WhatisthetensioninthestringwhenYes.Lightreflectedoffglassispartiallytheobjectisatthetopofitspath?polarized,sopolarizingsunglasseswillFreducemuchoftheglare,ifthesun-net�T�Fgglassesarealignedcorrectly.T�Fnet�Fg�1.9�102N�0.20�102NWritinginPhysics2NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page454�1.7�1073.Writeanessaydescribingthehistoryofhumanunderstandingofthespeedoflight.Includesignificantindividualsandthecon-tributionthateachindividualmade.Answerswillvary.Physics:PrinciplesandProblemsSolutionsManual355
359Chapter16continued76.Aspaceprobewithamassof7.600�103kg1.Youobservethatsomelightpassesistravelingthroughspaceat125m/s.throughfilter2,thoughnolightpassedMissioncontroldecidesthatacoursecor-throughfilter2previoustoinsertingtherectionof30.0°isneededandinstructstheanalyzerfilter.Whydoesthishappen?probetofirerocketsperpendiculartoitsTheanalyzerfilterallowssomelighttopresentdirectionofmotion.Ifthegaspassthrough,sinceitspolarizingaxisexpelledbytherocketshasaspeedofisnotperpendiculartothepolarizing3.200km/s,whatmassofgasshouldbeaxisofthefirstfilter.Thelastpolarizingreleased?(Chapter9)filternowcanpasslightfromtheana-mlyzerfilter,sincethepolarizingaxisofg�vgtan30.0°��theanalyzerfilterisnotperpendicularmpvp1tothepolarizingaxisofthelastpolariz-mpvp1(tan30.0°)ingfilter.m��g��vg2.Theanalyzerfilterisplacedatanangleof�(7.600�103kg)(125m/s)(tan30.0°)�����relativetothepolarizingaxesoffilter1.3.200�103m/sDeriveanequationfortheintensityoflight�171kgcomingoutoffilter2comparedtotheintensityoflightcomingoutoffilter1.77.Whena60.0-cm-longguitarstringisIpluckedinthemiddle,itplaysanoteoffre-1isthelightintensityoutofthefirstfil-ter,Iquency440Hz.Whatisthespeedoftheanalyzeristhelightintensityoutoftheanalyzerfilter,andIwavesonthestring?(Chapter14)2isthelightintensityoutofthelastfilter.��2L�2(0.600m)�1.20mI2�v��f�(1.20m)(440Hz)�530m/sanalyzer�I1cosI2(90°��)78.Whatisthewavelengthofasoundwave2�Ianalyzercoswithafrequencyof17,000HzinwateratI2(�)cos2(90°��)2�I1cos25°C?(Chapter15)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.v1493m/sFilter1Polarized�������0.0878m�8.8cmf17,000HzlightAnalyzerChallengeProblem�page444YouplaceananalyzerfilterbetweenthetwoFilter290°��cross-polarizedfilters,suchthatitspolarizing�axisisnotparalleltoeitherofthetwofilters,asshowninthefiguretotheright.Polarizingaxes356SolutionsManualPhysics:PrinciplesandProblems
360CHAPTER17ReflectionandMirrors�PracticeProblemsr1��i1�30°�i2�90°��r117.1ReflectionfromPlane�90°�30°�60°Mirrorspages457–463page460SectionReview1.Explainwhythereflectionoflightoff17.1ReflectionfromPlanegroundglasschangesfromdiffusetospecularifyouspillwateronit.Mirrorspages457–463Waterfillsintheroughareasandmakesthesurfacesmoother.page4636.ReflectionAlightraystrikesaflat,smooth,2.Iftheangleofincidenceofarayoflightisreflectingsurfaceatanangleof80°tothe42°,whatiseachofthefollowing?normal.Whatistheanglethatthereflecteda.theangleofreflectionraymakeswiththesurfaceofthemirror?�r��i�42°�r��ib.theangletheincidentraymakeswith�80°themirror�r,mirror�90°��r��90°�80°i,mirror�90°��i�90°�42°�48°c.theanglebetweentheincidentrayand�10°thereflectedray7.LawofReflectionExplainhowthelawof�i��r�2�i�84°reflectionappliestodiffusereflection.3.IfalightrayreflectsoffaplanemirroratanThelawofreflectionappliestoindivid-angleof35°tothenormal,whatwastheualraysoflight.Roughsurfacesmakeangleofincidenceoftheray?thelightraysreflectinmanydifferentdirections.�i��r�35°8.ReflectingSurfacesCategorizeeachofthe4.Lightfromalaserstrikesaplanemirroratfollowingasaspecularoradiffusereflect-anangleof38°tothenormal.Ifthelaseringsurface:paper,polishedmetal,windowismovedsothattheangleofincidenceglass,roughmetal,plasticmilkjug,smoothincreasesby13°,whatisthenewangleofwatersurface,andgroundglass.reflection?Specular:windowglass,smoothwater,�i��i,initial�13°polishedmetal.Diffuse:paper,rough�38°�13°�51°metal,groundglass,plasticmilkjug.�r��i�51°9.ImagePropertiesA50-cm-talldogstandsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.5.Twoplanemirrorsarepositionedatright3mfromaplanemirrorandlooksatitsanglestooneanother.Arayoflightstrikesimage.Whatistheimageposition,height,onemirroratanangleof30°totheandtype?normal.Itthenreflectstowardtheseconddmirror.Whatistheangleofreflectionofi�do�3mthelightrayoffthesecondmirror?Physics:PrinciplesandProblemsSolutionsManual357
361Chapter17continuedh13.Anobjectis36.0cminfrontofaconcavei�ho�50cmmirrorwitha16.0-cmfocallength.Determinetheimageposition.Theimageisvirtual.111��������fdd10.ImageDiagramAcarisfollowinganotheroicardownastraightroad.Thefirstcarhasadforearwindowtilted45°.Drawaraydiagramdi��d��foshowingthepositionoftheSunthatwould(36.0cm)(16.0cm)causesunlighttoreflectintotheeyesofthe����36.0cm�16.0cmdriverofthesecondcar.�28.8cmTheSun14.A3.0-cm-tallobjectis20.0cmfromaRearwindow16.0-cm-radiusconcavemirror.Determine45°offirstcartheimagepositionandimageheight.Driverof45°111��������secondcarfddoi45°Roadgradedfod��i�d�fTheSun’spositiondirectlyoverheadowouldlikelyreflectlightintothedriver’s16.0cm(20.0cm)����eyes,accordingtothelawofreflection.2����13.3cm16.0cm20.0cm�����211.CriticalThinkingExplainhowdiffusereflectionoflightoffanobjectenablesyouhi�dim������toseeanobjectfromanyangle.hodoTheincominglightreflectsoffthesur-�diho�(13.3cm)(3.0cm)h������faceoftheobjectinalldirections.Thisi�d20.0cmoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.enablesyoutoviewtheobjectfromany��2.0cmlocation.15.Aconcavemirrorhasa7.0-cmfocallength.A2.4-cm-tallobjectis16.0cmfromthePracticeProblemsmirror.Determinetheimageheight.17.2CurvedMirrors111��������fddpages464–473oipage469dofd��12.Usearaydiagram,drawntoscale,tosolvei�d�foExampleProblem2.(16.0cm)(7.0cm)����16.0cm�7.0cmO1Ray1�12.4cmRay2h�diim������Horizontalscale:CFhdoo1block�1.0cmI1Verticalscale:�diho3blocks�1.0cmhi��do�(12.4cm)(2.4cm)����16.0cm��1.9cm358SolutionsManualPhysics:PrinciplesandProblems
362Chapter17continued16.Anobjectisnearaconcavemirrorofdofd��10.0-cmfocallength.Theimageis3.0cmi�do�ftall,inverted,and16.0cmfromthemirror.(60.0cm)(�13.0cm)Whataretheobjectpositionandobject����60.0cm�(�13.0cm)height?��10.7cm111��������fdodihi�dim������hddfood�i�o�d�fi�(�10.7cm)m���(16.0cm)(10.0cm)60.0cm����16.0cm�10.0cm��0.178�26.7cmhi�mho�(0.178)(6.0cm)h�dii�1.1cmm������hdoo19.Aconvexmirrorisneededtoproducean�dhoiho��d�imagethatisthree-fourthsthesizeofaniobjectandlocated24cmbehindthemir-�(26.7cm)(�3.0cm)ror.Whatfocallengthshouldbespecified?����16.0cm111���������5.0cmfdidod�dodiif��andm���page472do�dido17.Anobjectislocated20.0cminfrontofa�dconvexmirrorwitha�15.0-cmfocalisod��o�mlength.Findtheimagepositionusingbothascalediagramandthemirrorequation.di��24cmandm�0.75,so�(�24cm)O1Ray1d��o�0.75I1Ray2F�32cmHorizontalscale:di��8.6cm(32cm)(�24cm)f����1block�1.0cm32cm�(�24cm)��96cm111��������ddfoi20.A7.6-cm-diameterballislocated22.0cmdoffromaconvexmirrorwitharadiusofcur-sod��i�d�fvatureof60.0cm.Whataretheball’simageopositionanddiameter?(20.0cm)(�15.0cm)����20.0cm�(�15.0cm)111��������fdd��8.57cmoidfod��18.Aconvexmirrorhasafocallengthofi�d�foCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�13.0cm.Alightbulbwithadiameterof(22.0cm)(�30.0cm)6.0cmisplaced60.0cmfromthemirror.����22.0cm�(�30.0cm)Whatisthelightbulb’simagepositionanddiameter?��12.7cm111��������ddfoiPhysics:PrinciplesandProblemsSolutionsManual359
363Chapter17continuedh�dii111m��������������hdfddoooi�dihodofhi���di��d��fdoo�(�12.7cm)(7.6cm)(20.0cm)(9.0cm)��������22.0cm20.0cm�9.0cm�4.4cm�16.4cm�di21.A1.8-m-tallgirlstands2.4mfromastore’sm���dosecuritymirror.Herimageappearstobe�16.4cm0.36mtall.Whatisthefocallengthofthe���20.0cmmirror?��0.82h�diim������hdoo24.ObjectPositionTheplacementofan�dhobjectinfrontofaconcavemirrorwithaoidi��h�focallengthof12.0cmformsarealimageothatis22.3cmfromthemirror.Whatisthe�(2.4m)(0.36m)����objectposition?1.8m111��0.48m��������fddoi111��������fdodidifd��o�d�fidf�id�o�(22.3cm)(12.0cm)d�dio����22.3cm�12.0cm(�0.48m)(2.4m)�����26.0cm�0.48m�2.4mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��0.60m25.ImagePositionandHeightA3.0-cm-tallobjectisplaced22.0cminfrontofaconcavemirrorhavingafocallengthofSectionReview12.0cm.Findtheimagepositionandheightbydrawingaraydiagramtoscale.17.2CurvedMirrorsVerifyyouranswerusingthemirrorandpages464–473magnificationequations.page47322.ImagePropertiesIfyouknowthefocalhi��3.6cmO1Ray1lengthofaconcavemirror,whereshoulddi�26.4cmFyouplaceanobjectsothatitsimageisCRay2uprightandlargercomparedtotheobject?Willthisproducearealorvirtualimage?I1Horizontalscale:1block�1.0cmYoushouldplacetheobjectbetweenVerticalscale:themirrorandthefocalpoint.The1block�1.0cmimagewillbevirtual.111��������23.MagnificationAnobjectisplaced20.0cmfddoiinfrontofaconcavemirrorwithafocaldflengthof9.0cm.Whatisthemagnificationod��i�d�foftheimage?o360SolutionsManualPhysics:PrinciplesandProblems
364Chapter17continued(22.0cm)(12.0cm)hi�di����m������22.0cm�12.0cmhdoo�26.4cm�dhoid��h�di�hiiom������hodo�(16.4cm)(2.8cm)�����dh6.0cmioh��i�d��7.7cmo111�(26.4cm)(3.0cm)������������fdodi22.0cmdd��3.6cmf�o�i�d�doi26.RayDiagramA4.0-cm-tallobjectis(�7.7cm)(16.4cm)located14.0cmfromaconvexmirrorwith�����7.7cm�16.4cmafocallengthof�12.0cm.Drawascale��14.5cmraydiagramshowingtheimagepositionr�2fandheight.Verifyyouranswerusingthemirrorandmagnificationequations.�(2)(�14.5cm)�29cmO1Ray1I28.FocalLengthAconvexmirrorisusedto1Ray2produceanimagethatistwo-thirdstheFsizeofanobjectandlocated12cmbehindHorizontalscale:1block�1.0cmhi�1.8cmthemirror.WhatisthefocallengthoftheVerticalscale:di��6.5cmmirror?3blocks�2.0cmh�diim������hdoo111�������fdodi�did��o�mdfodi��d��f�(�12cm)o��2����(14.0cm)(�12.0cm)3����14.0cm�(�12.0cm)�18cm��6.46cm111��������fddh�doiiim������hodododif���d�doi�dhiohi��d�(�12cm)(18cm)o�����12cm�18cm�(�6.46cm)(4.0cm)������36cm14.0cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.8cm29.CriticalThinkingWouldsphericalaberra-tionbelessforamirrorwhoseheight,27.RadiusofCurvatureA6.0-cm-tallobjectcomparedtoitsradiusofcurvature,isisplaced16.4cmfromaconvexmirror.Ifsmallorlarge?Explain.theimageoftheobjectis2.8cmtall,whatItwouldbelessforamirrorwhoseistheradiusofcurvatureofthemirror?heightisrelativelysmallcomparedtoPhysics:PrinciplesandProblemsSolutionsManual361
365Chapter17continueditsradiusofcurvature;diverginglight34.Describethepropertiesofaplanemirror.raysfromanobjectthatstrikethemir-(17.1)roraremoreparaxialsotheyconvergeAplanemirrorisaflat,smoothmorecloselytocreateanimagethatissurfacefromwhichlightisreflectedbynotblurred.specularreflection.Theimagescreatedbyplanemirrorsarevirtual,upright,andasfarbehindthemirrorastheChapterAssessmentobjectisinfrontofit.ConceptMapping35.Astudentbelievesthatverysensitivepage478photographicfilmcandetectavirtual30.Completethefollowingconceptmapusingimage.Thestudentputsphotographicfilmthefollowingterms:convex,upright,inverted,atthelocationofavirtualimage.Doesthisreal,virtual.attemptsucceed?Explain.(17.1)No,theraysdonotconvergeatavirtualMirrorsimage.Noimageformsandthestudentwouldnotgetapicture.Somevirtualimagesarebehindthemirror.planeconcaveconvex36.Howcanyouprovetosomeonethatanimageisarealimage?(17.1)virtualrealvirtualvirtualPlaceasheetofplainpaperorphoto-graphicfilmattheimagelocationanduprightinverteduprightuprightyoushouldbeabletofindtheimage.37.AnobjectproducesavirtualimageinaMasteringConceptsconcavemirror.Whereistheobjectlocated?page478(17.2)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.31.HowdoesspecularreflectiondifferfromObjectmustbelocatedbetweenFanddiffusereflection?(17.1)themirror.Whenparallellightisreflectedfromasmoothsurface,theraysarereflected38.Whatisthedefectthatallconcavesphericalparalleltoeachother.Theresultisanmirrorshaveandwhatcausesit?(17.2)imageoftheoriginoftherays.WhenRaysparalleltotheaxisthatstrikethelightisreflectedfromaroughsurface,itedgesofaconcavesphericalmirrorareisreflectedinmanydifferentdirections.notreflectedthroughthefocalpoint.Theraysarediffusedorscattered.NoThiseffectiscalledsphericalaberration.imageofthesourceresults.39.Whatistheequationrelatingthefocalpoint,32.Whatismeantbythephrase“normaltotheobjectposition,andimageposition?(17.2)surface”?(17.1)111��������anylinethatisperpendiculartothefddiosurfaceatanypoint40.Whatistherelationshipbetweenthe33.Whereistheimageproducedbyaplanecenterofcurvatureandthefocallengthmirrorlocated?(17.1)ofaconcavemirror?(17.2)TheimageisonalinethatisC�2fperpendiculartothemirrorandthesamedistancebehindthemirrorastheobjectisinfrontofthemirror.362SolutionsManualPhysics:PrinciplesandProblems
366Chapter17continued41.Ifyouknowtheimagepositionandobject46.Locateanddescribethephysicalpropertiespositionrelativetoacurvedmirror,howcanoftheimageproducedbyaconcavemirroryoudeterminethemirror’smagnification?whentheobjectislocatedatthecenterof(17.2)curvature.ThemagnificationisequaltotheTheimagewillbeatC,thecenterofnegativeoftheimagedistancedividedcurvature,inverted,real,andthesamebytheobjectdistance.sizeastheobject.42.Whyareconvexmirrorsusedasrearview47.Anobjectislocatedbeyondthecenterofmirrors?(17.2)curvatureofasphericalconcavemirror.ConvexmirrorsareusedasrearviewLocateanddescribethephysicalpropertiesmirrorsbecausetheyallowforawideoftheimage.rangeofview,allowingthedrivertoseeTheimagewillbebetweenCandF,andamuchlargerareathanisaffordedbywillbeinverted,real,andsmallerthanordinarymirrors.theobject.43.Whyisitimpossibleforaconvexmirrorto48.TelescopeYouhavetoorderalargeformarealimage?(17.2)concavemirrorforatelescopethatThelightraysalwaysdiverge.produceshigh-qualityimages.ShouldyouorderasphericalmirrororaparabolicApplyingConceptsmirror?Explain.pages478–479Youshouldorderaparabolicmirrorto44.WetRoadAdryroadismoreofaeliminatesphericalaberrations.diffusereflectorthanawetroad.Based49.DescribethepropertiesoftheimageseeninonFigure17-16,explainwhyawetthesingleconvexmirrorinFigure17-17.roadappearsblackertoadriverthanadryroaddoes.WetasphaltDryasphalt■Figure17-16Lesslightisreflectedbacktothecarfromawetroad.45.BookPagesWhyisitdesirablethatthe■Figure17-17pagesofabookberoughratherthanTheimageinasingleconvexmirrorisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.smoothandglossy?alwaysvirtual,erect,smallerthantheThesmootherandglossierthepagesobject,andlocatedclosertothemirrorare,thelesserthediffusereflectionofthantheobject.lightandthegreatertheglarefromthepages.Physics:PrinciplesandProblemsSolutionsManual363
367Chapter17continued50.Listallthepossiblearrangementsinwhich55.Arayoflightincidentuponamirrormakesyoucoulduseasphericalmirror,eitheranangleof36°withthemirror.Whatistheconcaveorconvex,toformarealimage.anglebetweentheincidentrayandtheYoucanuseonlyaconcavemirrorwithreflectedray?theobjectbeyondthefocalpoint.Acon-�i�90°�36°vexmirrorwillnotformarealimage.�54°�51.Listallpossiblearrangementsinwhichyour��icoulduseasphericalmirror,eitherconcave�54°orconvex,toformanimagethatissmaller���i��rcomparedtotheobject.�54°�54°Youmayuseaconcavemirrorwiththe�108°objectbeyondthecenterofcurvatureoraconvexmirrorwiththeobjectLevel2anywhere.56.PictureinaMirrorPennywishestotakeapictureofherimageinaplanemirror,as52.RearviewMirrorsTheoutsiderearviewshowninFigure17-18.Ifthecameraismirrorsofcarsoftencarrythewarning1.2minfrontofthemirror,atwhatdis-“Objectsinthemirrorarecloserthantheytanceshouldthecameralensbefocused?appear.”Whatkindofmirrorsaretheseandwhatadvantagedotheyhave?Convexmirror;itprovidesawiderfieldofview.MasteringProblems17.1ReflectionfromPlaneMirrorspage479Level1Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.53.Arayoflightstrikesamirroratanangleof38°tothenormal.Whatistheanglethatthereflectedanglemakeswiththenormal?�r��i�38°54.Arayoflightstrikesamirroratanangleof53°tothenormal.■Figure17-18a.Whatistheangleofreflection?Theimageis1.2mbehindthemirror,so�r��ithecameralensshouldbesetto2.4m.�53°b.Whatistheanglebetweentheincident57.Twoadjacentplanemirrorsformarightrayandthereflectedray?angle,asshowninFigure17-19.Alightrayisincidentupononeofthemirrorsatan���i��rangleof30°tothenormal.�53°�53°�106°364SolutionsManualPhysics:PrinciplesandProblems
368Chapter17continuedthefeethitsthemirrorhalfwaybetweentheeyesandthefeet.Thedistancebetweenthepointthetworayshitthemirrorishalfthetotalheight.Level330°59.Twoplanemirrorsareconnectedattheirsidessothattheyforma45°anglebetweenthem.Alightraystrikesonemirroratan■Figure17-19angleof30°tothenormalandthenreflectsa.Whatistheangleatwhichthelightrayoffthesecondmirror.Calculatetheangleofisreflectedfromtheothermirror?reflectionofthelightrayoffthesecondmirror.Reflectionfromthefirstmirror:Reflectionfromthefirstmirroris�r1��i1�30°�Reflectionfromthesecondmirror:r,1��i,1�30°.Theangletherayformswiththemirroristhus90°�30°��i2�90°��r160°.Becausethetwomirrorsforma45°�90°�30°angle,theangletherayreflectingoff�60°thefirstmirrorformswiththesecond�mirroris180°�60°�45°�75°.Ther2��i2angletherayformswiththesecond�60°mirroristhus�i,2�90°�75°�15°.b.AretroreflectorisadevicethatreflectsTheangleofreflectionfromthesecondincominglightraysbackinadirectionmirroris�oppositetothatoftheincidentrays.r,2��i,2�15°.Drawadiagramshowingtheangleof60.Arayoflightstrikesamirroratanangleofincidenceonthefirstmirrorforwhich60°tothenormal.Themirroristhenrotatedthemirrorsystemactsasaretroreflector.18°clockwise,asshowninFigure17-20.Whatistheanglethatthereflectedraymakeswiththemirror?Incidentlight45°18°60°58.DrawaraydiagramofaplanemirrortoNormalshowthatifyouwanttoseeyourselffromyourfeettothetopofyourhead,themirrormustbeatleasthalfyourheight.EyeMirrorImageMirrorlevelCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Feet■Figure17-20�i��i,old�18°Therayfromthetopoftheheadhits�60°�18°themirrorhalfwaybetweentheeyes�42°andthetopofthehead.TherayfromPhysics:PrinciplesandProblemsSolutionsManual365
369Chapter17continued�r��i�42°�r,mirror�90°��r�90°�42°�48°CF17.2CurvedMirrorspage480Level161.Aconcavemirrorhasafocallengthof■Figure17-2110.0cm.Whatisitsradiusofcurvature?real;inverted;largerr�2f�2(10.0cm)�20.0cmLevel262.Anobjectlocated18cmfromaconvex65.StarImageLightfromastariscollectedbymirrorproducesavirtualimage9cmfromaconcavemirror.Howfarfromthemirrorthemirror.Whatisthemagnificationoftheistheimageofthestariftheradiusofimage?curvatureis150cm?�diStarsarefarenoughawaythatthem���dolightcomingintothemirrorcanbe�(�9cm)consideredtobeparallelandparallel���18cmlightwillconvergeatthefocalpoint.�0.5Sincer�2f,r150cm63.FunHouseAboyisstandingnearaf��2���2��75cmconvexmirrorinafunhouseatafair.Henoticesthathisimageappearstobe66.FindtheimagepositionandheightfortheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.0.60mtall.IfthemagnificationoftheobjectshowninFigure17-22.1mirroris��,whatistheboy’sheight?3him���hohi3.8cmh��Fo�m0.60m16cm��131cm����3�1.8m64.Describetheimageproducedbytheobject■Figure17-22inFigure17-21asrealorvirtual,invertedorupright,andsmallerorlargerthanthe111��������fddobject.oidfod��i�d�fo(31cm)(16cm)���31cm�16cm366SolutionsManualPhysics:PrinciplesandProblems
370Chapter17continued�33cmwhatisthemagnificationoftheimage?h�df�r���(40mm)��20mmii�m������22hdoo111���������dihododifh��i�dodf(16mm)(20mm)od�������80mm�(33cm)(3.8cm)i�d�f16mm�20mm����o31cm�di�(�80mm)��4.1cmm�������5d16mmo67.RearviewMirrorHowfardoestheimage70.A3.0-cm-tallobjectis22.4cmfromaofacarappearbehindaconvexmirror,concavemirror.Ifthemirrorhasaradiusofwithafocallengthof�6.0m,whenthecarcurvatureof34.0cm,whataretheimageis10.0mfromthemirror?positionandheight?111��������rfdodif���2dof34.0cmd�����i�d�f2o(10.0m)(�6.0m)�17.0cm����10.0m�(�6.0m)111��������fdd��3.8moidfo68.Anobjectis30.0cmfromaconcavemirrordi��d��foof15.0cmfocallength.Theobjectis(22.4cm)(17.0cm)1.8cmtall.Usethemirrorequationto����22.4cm�17.0cmfindtheimageposition.Whatistheimageheight?�70.5cm111h�d��������iiddfm������oihdoodfo�dhd��ioi�d�fhi���odo(30.0cm)(15.0cm)�����(70.5cm)(3.0cm)30.0cm�15.0cm����22.4cm�30.0cm��9.4cmh�diim������hdLevel3oo71.Jeweler’sMirrorAjewelerinspectsa�dhioh��watchwithadiameterof3.0cmbyplacingi�doit8.0cminfrontofaconcavemirrorof�(30.0cm)(1.8cm)12.0-cmfocallength.����(30.0cm)a.WherewilltheimageofthewatchCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��1.8cmappear?11169.DentalMirrorAdentistusesasmallmir-�d���d���f�oirorwitharadiusof40mmtolocateacavityinapatient’stooth.Ifthemirrorisconcaveandisheld16mmfromthetooth,Physics:PrinciplesandProblemsSolutionsManual367
371Chapter17continueddof(8.0cm)(12.0cm)111d��������������i�d�f8.0cm�12.0cmdodifo��24cmfdod��b.Whatwillbethediameteroftheimage?i�d�fohi�di(�10.0cm)(150cm)�����������9.4cmhd150cm�(�10.0cm)oo�diho�(�24cm)(3.0cm)�di�(�9.4cm)h������m��������0.063i�do8.0cmdo150cm�9.0cmhi�mho�(0.063)(12cm)�0.75cm72.SunlightfallsonaconcavemirrorandMixedReviewformsanimagethatis3.0cmfromthepages480–481mirror.Anobjectthatis24mmtallisLevel1placed12.0cmfromthemirror.74.Alightraystrikesaplanemirroratananglea.Sketchtheraydiagramtoshowtheof28°tothenormal.Ifthelightsourceislocationoftheimage.movedsothattheangleofincidenceincreasesby34°,whatisthenewangleofO1Ray1reflection?Ray2�i��i,initial�34°CF�28°�34°Horizontalscale:I11block�1.0cm�62°Verticalscale:�1block�4mmr��i�62°b.Usethemirrorequationtocalculatetheimageposition.75.CopyFigure17-23onasheetofpaper.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Drawraysonthediagramtodeterminethe111��������heightandlocationoftheimage.ddfoifd(3.0cm)(12.0cm)d�o���i�d�12.0cm�3.0cmo�f�4.0cmc.Howtallistheimage?3.0cmF�di�4.0cmm��������0.338.0cm4.0cmd12.0cmohi�mho�(�0.33)(24mm)��8.0mm73.Shinyspheresthatareplacedonpedestals■Figure17-23onalawnareconvexmirrors.Onesuchspherehasadiameterof40.0cm.A12-cm-tallrobinsitsinatreethatis1.5mfromthesphere.Whereistheimageoftherobinandhowtallistheimage?r�20.0cm,f��10.0cm368SolutionsManualPhysics:PrinciplesandProblems
372Chapter17continuedb.Whatistheimageheight?O1Ihi�1.0cmhi1d��2.7cmm���ihoHorizontalscale:F�dhio1block�1.0cmhi��d�Verticalscale:o2blocks�1.0cm�(22.9cm)(2.4cm)����30.0cmTheimageheightis1.0cm,andits��1.8cmlocationis2.7cmfromthemirror.78.WhatistheradiusofcurvatureofaconcaveLevel2mirrorthatmagnifiesanobjectbyafactor76.Anobjectislocated4.4cminfrontofaof�3.2whentheobjectisplaced20.0cmconcavemirrorwitha24.0-cmradius.fromthemirror?Locatetheimageusingthemirrorequation.hirm���f���ho224.0cmdi��mdo���2��(3.2)(20.0cm)�12.0cm��64cm111��������fdodi�1���1���1�fddoidfod��i�do�fdodif���d�doi(4.4cm)(12.0cm)����4.4cm�12.0cm(20.0cm)(�64cm)����20.0cm�(�64cm)��6.9cm�29cm77.Aconcavemirrorhasaradiusofcurvaturer�2fof26.0cm.Anobjectthatis2.4cmtallis�(2)(29cm)placed30.0cmfromthemirror.�58cma.Whereistheimageposition?r79.Aconvexmirrorisneededtoproduceanf���2imageone-halfthesizeofanobjectand26.0cmlocated36cmbehindthemirror.What���2focallengthshouldthemirrorhave?�13.0cmh�diim������111hd��������oofddoi�dhiodofdo��h�d��ii�d�fo�(�36cm)hoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(30.0cm)(13.0cm)���ho����30.0cm�13.0cm����2�22.9cm�72cm111��������fddoiPhysics:PrinciplesandProblemsSolutionsManual369
373Chapter17continueddodia.Whatkindofmirrorwoulddothisjob?f���d�doiAnenlarged,uprightimageresults(72cm)(�36cm)onlyfromaconcavemirror,withthe����objectinsidethefocallength.72cm�(�36cm)��72cmb.Whatisitsradiusofcurvature?�di80.SurveillanceMirrorAconveniencestorem��d�ousesasurveillancemirrortomonitorthedstore’saisles.Eachmirrorhasaradiusofi��mdo��(7.5)(14.0mm)curvatureof3.8m.��105mma.Whatistheimagepositionofacustomer111��������whostands6.5minfrontofthemirror?dodifAmirrorthatisusedforsurveillancedodi(14.0mm)(�105mm)f�������isaconvexmirror.Sothefocald�d14.0mm�(�105mm)iolengthisthenegativeofhalfthe�16mmradiusofcurvature.r�2f�(2)(16mm)�rf��2��32mm�3.8m���82.TheobjectinFigure17-24movesfrom2position1toposition2.Copythediagram��1.9montoasheetofpaper.Drawraysshowing111��������howtheimagechanges.fddoidfod��i�d�fo(6.5m)(�1.9m)����16.5m�(�1.9m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.C2F��1.5m1.0mb.Whatistheimageheightofacustomer1.5mwhois1.7mtall?2.0mh�d2.5miim������hdoo■Figure17-24�dhioh��i�doO1Ray1O2Ray1�(�1.5m)(1.7m)Ray2Ray2����6.5m1C2FI1�0.38mI2Horizontalscale:Level31block�10cm81.InspectionMirrorAproduction-lineinspectorwantsamirrorthatproducesan83.Aballispositioned22cminfrontofaspheri-imagethatisuprightwithamagnificationcalmirrorandformsavirtualimage.Iftheof7.5whenitislocated14.0mmfromasphericalmirrorisreplacedwithaplanemir-machinepart.ror,theimageappears12cmclosertothemir-ror.Whatkindofsphericalmirrorwasused?370SolutionsManualPhysics:PrinciplesandProblems
374Chapter17continuedTheobjectpositionforbothmirrorsisORay1122cm.So,theimagepositionfortheRay2Horizontalscale:planemirroris�22cm.1block�1.0mBecausethesphericalmirrorformsaCFVerticalscale:hi�2.4m2blocks�1.0mvirtualimage,theimageislocateddi�14mbehindthemirror.Thus,theimageposi-I1tionforthesphericalmirrorisnegative.Theimageis2.4mtall,anditis14mdi�di,plane�12cmfromthemirror.��22cm�12cm86.A4.0-cm-tallobjectisplaced12.0cmfroma��34cmconvexmirror.Iftheimageoftheobjectis1112.0cmtall,andtheimageislocatedat��������fddoi�6.0cm,whatisthefocallengthofthemir-ddror?Drawaraydiagramtoanswertheques-f�o�i�tion.Usethemirrorequationandthemag-d�doinificationequationtoverifyyouranswer.(22cm)(�34cm)����22cm�(�34cm)O1Ray1I1�62cmRay2Thefocallengthispositive,sotheHorizontalscale:Fsphericalmirrorisaconcavemirror.1block�1.0cmf��12cmVerticalscale:84.A1.6-m-tallgirlstands3.2mfromaconvex3blocks�2.0cmmirror.Whatisthefocallengthofthemirrorifherimageappearstobe0.28mtall?111��������fddh�doiiim������hodododif���d�d�hdoiiod��i�ho(12.0cm)(�6.0cm)����12.0cm�(�6.0cm)�(0.28m)(3.2m)����1.6m��12cm��0.56mThinkingCritically111��������pages481–482fddoi87.ApplyConceptsTheballinFigure17-25dodislowlyrollstowardtheconcavemirroronthef���d�doiright.Describehowthesizeoftheball’simage(3.2m)(�0.56m)changesasitrollsalong.����3.2m�(�0.56m)��0.68mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.85.MagicTrickAmagicianusesaconcaveCFmirrorwithafocallengthof8.0mtomakea3.0-m-tallhiddenobject,located18.0mfromthemirror,appearasarealimagethatisseenbyhisaudience.Drawascaleraydiagramtofindtheheightandlocationoftheimage.■Figure17-25Physics:PrinciplesandProblemsSolutionsManual371
375Chapter17continuedBeyondC,theimageissmallerthanthemirror,whatisthefocallengthofthecon-ball.Astheballrollstowardthemirror,cavemirror?theimagesizeincreases.Theimageisdi,initial�do,initialthesamesizeastheballwhentheballisatC.Theimagesizecontinuesto�6.0cmincreaseuntilthereisnoimagewhendtheballisatF.PastF,thesizeofthei�di,initial�(�8.0cm)imagedecreasesuntilitequalsthe��6.0cm�(�8.0cm)ball’ssizewhentheballtouchesthe��14.0cmmirror.111��������88.AnalyzeandConcludeTheobjectinfdodiFigure17-26islocated22cmfromaddf�o�iconcavemirror.Whatisthefocallength�d�doiofthemirror?(6.0cm)(�14.0cm)f����6.0cm�(�14.0cm)f�1.0�101cm91.AnalyzeandConcludeThelayoutofthetwo-mirrorsystemshowninFigure17-11isthatofaGregoriantelescope.Forthis22cmquestion,thelargerconcavemirrorhasaradiusofcurvatureof1.0m,andthesmallermirrorislocated0.75maway.Whyisthesecondarymirrorconcave?Thesmallermirrorisconcavetoproduce■Figure17-26arealimageattheeyepiecethatisrCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.f���upright.Thelightraysareinvertedbythe2firstconcavemirrorandtheninverteddoagainbythesecondaryconcavemirror.���222cm92.AnalyzeandConcludeAnopticalarrange-���2mentusedinsometelescopesisthe�11cmCassegrainfocus,showninFigure17-27.Thistelescopeusesaconvexsecondary89.UseEquationsShowthatastheradiusofmirrorthatispositionedbetweenthecurvatureofaconcavemirrorincreasestoprimarymirrorandthefocalpointofinfinity,themirrorequationreducestothetheprimarymirror.relationshipbetweentheobjectpositionConvexConcaveandtheimagepositionforaplanemirror.secondarymirrorprimarymirrorAsf→�,1/f→0.Themirrorequationthenbecomes1/do��1/di,ordo��di.F90.AnalyzeandConcludeAnobjectislocated6.0cmfromaplanemirror.Iftheplanemir-rorisreplacedwithaconcavemirror,theTelescopetubeEyepieceresultingimageis8.0cmfartherbehindthe■Figure17-27mirror.Assumingthattheobjectislocateda.Asingleconvexmirrorproducesonlybetweenthefocalpointandtheconcavevirtualimages.Explainhowtheconvex372SolutionsManualPhysics:PrinciplesandProblems
376Chapter17continuedmirrorinthistelescopefunctionswithinb.theprecisionopticalpolishingofalu-thesystemofmirrorstoproducerealminumtosuchadegreeofsmoothnessimages.thatnoglassisneededintheprocessofTheconvexmirrorisplacedtointer-makingamirrorcepttheraysfromaconcavemirrorAnswerswillvary.Studentanswersbeforetheyconverge.Theconvexmightincludeinformationaboutmirrorplacesthepointofconver-deformationofamirrorfromitsowngenceintheoppositedirectionbackweightassizeincreasesandhowatowardtheconcavemirror,andmirrormadeofaluminumcouldlengthensthetotaldistancethelightimpactthisproblem.travelsbeforeconverging.ThiseffectivelyincreasesthefocallengthCumulativeReviewcomparedtousingtheconcavemir-page482rorbyitself,thusincreasingthe95.Achildrunsdowntheschoolhallwayandtotalmagnification.thenslidesonthenewlywaxedfloor.Heb.Aretheimagesproducedbythewasrunningat4.7m/sbeforehestartedCassegrainfocusuprightorinverted?slidingandheslid6.2mbeforestopping.HowdoesthisrelatetothenumberofWhatwasthecoefficientoffrictionofthetimesthatthelightcrosses?waxedfloor?(Chapter11)Inverted;eachtimethelightraysTheworkdonebythewaxedfloorcrosstheimageinverts.equalsthechild’sinitialkineticenergy.KE�1�mv2�W�Fd���2kmgdWritinginPhysicsThemassofthechildcancelsout,givingpage482v2���93.Researchamethodusedforgrinding,polish-k�2gding,andtestingmirrorsusedinreflecting2(4.7m/s)telescopes.Youmayreporteitheronmeth-����2)(6.2m)(2)(9.80m/sodsusedbyamateurastronomerswhomake�0.18theirowntelescopeoptics,oronamethodusedbyaprojectatanationallaboratory.96.A1.0gpieceofcopperfallsfromaheightofPrepareaone-pagereportdescribingthe4mfromanairplanetotheground.1.0�10method,andpresentittotheclass.BecauseofairresistanceitreachesthegroundAnswerswillvarydependingonthemovingatavelocityof70.0m/s.Assumingmirrorsandmethodschosenbythestu-thathalfoftheenergylostbythepiecewasdis-dents.Amateurmethodsusuallyinvolvetributedasthermalenergytothecopper,howrubbingtwo“blanks”againsteachothermuchdiditheatduringthefall?(Chapter12)withvaryinggritsbetweenthem.PotentialenergyofthepieceMethodsusedatnationallabsvary.E�mgh94.Mirrorsreflectlightbecauseoftheirmetal-�(0.0010kg)(9.80m/s2)(1.0�104m)liccoating.Researchandwriteasummary�9.8Jofoneofthefollowing:Finalenergya.thedifferenttypesofcoatingsusedandCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12theadvantagesanddisadvantagesofeachEf��2�mvAnswerswillvary.Studentanswers1���(0.0010kg)(70.0m/s)2shouldincludeinformationabout2shininessaswellastarnish�2.4Jresistance.Physics:PrinciplesandProblemsSolutionsManual373
377Chapter17continuedHeataddedtothepiece99.OrganpipesAnorganbuildermustdesign1apipeorganthatwillfitintoasmallspace.Q���(E�E2f)(Chapter15)1a.Shouldhedesigntheinstrumenttohave���(9.8J�2.4J)2openpipesorclosedpipes?Explain.�3.7JTheresonantfrequencyofanopenQpipeistwicethatofaclosedpipe�T���mcofthesamelength.Therefore,the3.7Jpipesofaclosed-pipeorganneed����(0.0010kg)(385J/kg°C)beonlyhalfaslongasopenpipes�9.5°Ctoproducethesamerangeoffundamentalfrequencies.97.Itispossibletoliftapersonwhoissittingonab.Willanorganconstructedwithopenpillowmadefromalargesealedplasticgarbagepipessoundthesameasonecon-bagbyblowingairintothebagthroughasodastructedwithclosedpipes?Explain.straw.Supposethatthecross-sectionalareaof2andNo.Whilethetwoorganswillhavethepersonsittingonthebagis0.25mthesamefundamentaltones,theperson’sweightis600N.Thesodastrawhasacross-sectionalareaof2�10�5m2.Withclosedpipesproduceonlytheoddharmonics,sotheywillhavediffer-whatpressuremustyoublowintothestrawtoenttimbresthanopenpipes.liftthepersonthatissittingonthesealedgarbagebag?(Chapter13)100.FiltersareaddedtoflashlightssothatoneApplyPascal’sprinciple.shinesredlightandtheothershinesgreenAlight.Thebeamsarecrossed.Explainin1�F��2��F1Atermsofwaveswhythelightfromboth2flashlightsisyellowwherethebeams2�10�5m2�(600N)���2��0.048Ncross,butrevertbacktotheiroriginal0.25mcolorsbeyondtheintersectionpoint.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�F20.048N(Chapter16)�P�������2.4kPaA22�10�5m2Wavescaninterfere,add,andthenor2kPatoonesignificantdigitpassthroughunaffected.Chapter14notaverylargepressureatallshowedtheamplitudeofwavesadding.Inthiscase,thewavesretain98.Whatwouldbetheperiodofa2.0-m-longtheircolorinformationastheycrosspendulumontheMoon’ssurface?Thethrougheachother.Moon’smassis7.34�1022kg,anditsradiusis1.74�106m.WhatistheperiodofthispendulumonEarth?(Chapter14)ChallengeProblemGmg�mpage470m�d2mAnobjectofheighthoislocatedatdorelativeto(6.67�10�11aconcavemirrorwithfocallengthf.�N�m2/kg2)(7.34�1022kg)1.Drawandlabelaraydiagramshowingthefocallengthandlocationoftheobjectifthe�1.62m/s2imageislocatedtwiceasfarfromthel2.0mmirrorastheobject.ProveyouranswerT���2����7.0sMoon�2���g��1.62m�/s2mathematically.Calculatethefocallengthl2.0masafunctionofobjectpositionforthisT���2����2.8sEarth�2���g��9.80m�/s2placement.374SolutionsManualPhysics:PrinciplesandProblems
378Chapter17continued111ORay1��������1fddoidi�2dORay2fdd��iCFo�d�f2dOif�3f(2f)��2f�f�1���1���1��2ffddoih�diiddm��h���d�f��o�iood�doi�dhh��iodo(2do)i�do���d�2doo�(2f)ho2d����o2f3��ho2.Drawandlabelaraydiagramshowingthelocationoftheobjectiftheimageislocated3.Whereshouldtheobjectbelocatedsothattwiceasfarfromthemirrorasthefocalnoimageisformed?point.Proveyouranswermathematically.TheobjectshouldbeplacedatthefocalCalculatetheimageheightasafunctionofpoint.theobjectheightforthisplacement.O1Ray1Ray2di�2fCFhi��hOI1Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual375
379
380CHAPTER18RefractionandLenses5.AblockofunknownmaterialissubmergedPracticeProblemsinwater.Lightinthewaterisincidenton18.1RefractionofLighttheblockatanangleofincidenceof31°.pages485–492Theangleofrefractionofthelightintheblockis27°.Whatistheindexofrefractionpage487ofthematerialoftheblock?1.Alaserbeaminairisincidentuponethanolatanangleofincidenceof37.0°.Whatisn1sin�1�n2sin�2theangleofrefraction?nn��1sin�1n2�sin�1sin�1�n2sin�22��1����n1sin�1�(1.33)(sin31°)��2�sinnsin27°2�1.5�1(1.00)(sin37.0°)�sin����1.36�26.3°SectionReview2.Lightinairisincidentuponapieceof18.1RefractionofLightcrownglassatanangleofincidenceofpages485–49245.0°.Whatistheangleofrefraction?page492n1sin�1�n2sin�26.IndexofRefractionYounoticethatwhen��1����n1sin�1alightrayentersacertainliquidfrom2�sinn2water,itisbenttowardthenormal,butwhenitentersthesameliquidfromcrown�1(1.00)(sin45.0°)�sin����1.52glass,itisbentawayfromthenormal.Whatcanyouconcludeabouttheliquid’sindex�27.7°ofrefraction?3.Lightpassesfromairintowaterat30.0°tonwater�nliquid�ncrownglass,therefore,thenormal.Findtheangleofrefraction.nliquidmustbebetween1.33and1.52.n1sin�1�n2sin�27.IndexofRefractionArayoflighthasann��1����1sin�1angleofincidenceof30.0°onablock2�sinn2ofunknownmaterialandanangleof�1(1.00)(sin30.0°)refractionof20.0°.Whatistheindexof�sin����1.33refractionofthematerial?�22.1°n1sin�1�n2sin�2n4.Lightisincidentuponadiamondfacetatn��1sin�12�sin�45.0°.Whatistheangleofrefraction?2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.n(1.00)(sin30.0°)1sin�1�n2sin�2���sin20.0°n��1����1sin�1�1.462�sinn2�1(1.00)(sin45.0°)�sin�����17.0°2.42Physics:PrinciplesandProblemsSolutionsManual377
381Chapter18continued8.SpeedofLightCouldanindexof14.CriticalThinkingInwhatdirectioncanrefractioneverbelessthan1?Whatwouldyouseearainbowonarainylateafter-thisimplyaboutthespeedoflightinthatnoon?Explain.medium?Intheeast,becausetheSunsetsintheNo,itwouldmeanthespeedoflightinwestandsunlightmustshinefromthemediumisfasterthanitisinabehindyouinorderforyoutoseeavacuum.rainbow.9.SpeedofLightWhatisthespeedoflightinchloroform(n�1.51)?PracticeProblemscn��18.2ConvexandConcavevcLensesv��chloroform�nchloroformpages493–4993.00�108m/spage496���1.5115.A2.25-cm-tallobjectis8.5cmtotheleftof�1.99�108m/saconvexlensof5.5-cmfocallength.Findtheimagepositionandheight.10.TotalInternalReflectionIfyouwereto111�����usequartzandcrownglasstomakeanfdodiopticalfiber,whichwouldyouuseforthedd�ofcladdinglayer?Why?i�do�fcrownglassbecauseithasalower(8.5cm)(5.5cm)indexofrefractionandwouldproduce����8.5cm�5.5cmtotalinternalreflection�15.6cm,or16cm11.AngleofRefractionAbeamoflighthi�dim����passesfromwaterintopolyethylenewithhodoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.n�1.50.If�i�57.5°,whatistheangleof�dihorefractioninthepolyethylene?hi��don1sin�1�n2sin�2�(15.6cm)(2.25cm)����n8.5cm��1����1sin�12�sinn��4.1cm2�1(1.33)(sin57.5°)�sin����16.Anobjectnearaconvexlensproducesa1.501.8-cm-tallrealimagethatis10.4cmfrom�48.4°thelensandinverted.Ifthefocallengthofthelensis6.8cm,whataretheobject12.CriticalAngleIsthereacriticalangleforpositionandheight?lighttravelingfromglasstowater?From111watertoglass?�����fddoiYes,becausenglass�nwater.No.dd�ifo�d13.DispersionWhycanyouseetheimageofi�ftheSunjustabovethehorizonwhenthe(10.4cm)(6.8cm)����Sunitselfhasalreadyset?10.4cm�6.8cmbecauseofbendingoflightraysinthe�2.0�101cmatmosphere;refraction378SolutionsManualPhysics:PrinciplesandProblems
382Chapter18continuedm�hi��didof��di��dhodoo�f�d(25cm)(5.0cm)h�ohi����o�d25cm�5.0cmi�6.2cm�(19.6cm)(�1.8cm)����10.4cmh�dm��i��ihd�3.4cmoo�dh�iho17.Anobjectisplacedtotheleftofaconvexi�dolenswitha25-mmfocallengthsothatitsimageisthesamesizeastheobject.What�����(6.2cm)(2.0cm)25cmaretheimageandobjectpositions?��0.50cm(invertedimage)111�����fddiowithdpage497o�dibecause20.Anewspaperisheld6.0cmfromaconvex�dm��iandm��1lensof20.0-cmfocallength.Findtheimagedopositionofthenewsprintimage.Therefore,111�����12fdido���fdidSod�ofdi�di�2fo�f�2(25mm)(6.0cm)(20.0cm)����6.0cm�20.0cm�5.0�101mm��8.6cmd1mmo�di�5.0�1021.Amagnifyingglasshasafocallengthof18.Useascaleraydiagramtofindtheimage12.0cm.Acoin,2.0cmindiameter,ispositionofanobjectthatis30cmtotheplaced3.4cmfromthelens.Locatetheleftofaconvexlenswitha10-cmfocalimageofthecoin.Whatisthediameteroflength.theimage?di�15cm111�����fddioO1Ray1dd�ofRay2di�15cmi�do�fFF(3.4cm)(12.0cm)Horizontalscale:����3.4cm�12.0cm1block�1cmI1��4.7cm19.Calculatetheimagepositionandheightof�hodi�(2.0cm)(�4.7cm)h����a2.0-cm-tallobjectlocated25cmfromai��d3.4cmoconvexlenswithafocallengthof5.0cm.�2.8cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Whatistheorientationoftheimage?111�����fddoiPhysics:PrinciplesandProblemsSolutionsManual379
383Chapter18continued22.AconvexlenswithafocallengthofThelocationshouldbeabout15cmon22.0cmisusedtoviewa15.0-cm-longthesamesideofthelens(�15cm)andpencillocated10.0cmaway.Findthetheimageshouldbeuprightandaboutheightandorientationoftheimage.1.5cmtall.111�����fddoiSectionReviewdd�ofi�do�f18.2ConvexandConcave(10.0cm)(22.0cm)Lenses����10.0cm�22.0cmpages493–499��18.3cmpage499hi�di25.MagnificationMagnifyingglassesnormal-m����hodolyareusedtoproduceimagesthatarelargerthantherelatedobjects,buttheyalsocan�dh�ihoi�dproduceimagesthataresmallerthantheorelatedobjects.Explain.�(�18.3cm)(15.0cm)����Iftheobjectislocatedfartherthan10.0cmtwicethefocallengthfromthelens,the�27.5cm(uprightimage)sizeoftheimageissmallerthanthesizeoftheobject.23.Astampcollectorwantstomagnifyastampby4.0whenthestampis3.5cmfromthe26.ImagePositionandHeightA3.0-cm-talllens.Whatfocallengthisneededfortheobjectislocated2.0cmfromaconvexlenslens?havingafocallengthof6.0cm.Drawaray�didiagramtodeterminethelocationandsizem��dooftheimage.Usethethinlensequationandthemagnificationequationtoverifydi��mdo��(4.0)(3.5cm)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.youranswer.��14cm111�����I1fddiod(3.5cm)(�14cm)O1f���odi���d3.5cm�(�14cm)FFo�diHorizontalscale:�4.7cm2blocks�1.0cmhi�4.5cmVerticalscale:24.Amagnifierwithafocallengthof30cmdi��3.0cm1block�1.0cmisusedtoviewa1-cm-tallobject.Useray111tracingtodeterminethelocationand�����fddoisizeoftheimagewhenthemagnifierisdpositioned10cmfromtheobject.d�ofi�do�f(2.0cm)(6.0cm)I1����2.0cm�6.0cmFFO1��3.0cmhi�1.5cmHorizontalscale:h�d�i�idi��15cm1block�2cmm��hdVerticalscale:oo3blocks�1cm380SolutionsManualPhysics:PrinciplesandProblems
384Chapter18continued�dh�ihoi�dWatero�(�3.0cm)(3.0cm)����2.0cm�4.5cmLightraysAir27.TypesofLensesThecrosssectionsoffourdifferentthinlensesareshowninFigure18-16.Water■Figure18-17Thelightrayswilldiverge.Water■Figure18-16a.Whichoftheselenses,ifany,areconvex,orconverging,lenses?Lightraysn�1.3n�1.0n�1.3Lensesaandcareconverging.b.Whichoftheselenses,ifany,areconcave,ordiverging,lenses?Lensesbanddarediverging.Water28.ChromaticAberrationAllsimplelenseshavechromaticaberration.Explain,then,SectionReviewwhyyoudonotseethiseffectwhenyoulookthroughamicroscope.18.3ApplicationsofLensesAllprecisionopticalinstrumentsusepages500–503acombinationoflenses,calledanpage503achromaticlens,tominimizechromatic31.RefractionExplainwhythecorneaistheaberration.primaryfocusingelementintheeye.Thedifferenceinindexofrefraction29.ChromaticAberrationYoushinewhitebetweentheairandthecorneaislightthroughaconvexlensontoascreengreaterthananyotherdifferencethatandadjustthedistanceofthescreenfromlightraysencounterwhentravelingthelenstofocustheredlight.Whichdirec-towardtheretina.tionshouldyoumovethescreentofocusthebluelight?32.LensTypesWhichtypeoflens,convexorclosertothelensconcave,shouldanearsightedpersonuse?Whichtypeshouldafarsightedpersonuse?30.CriticalThinkingAnairlensconstructedAnearsightedpersonshoulduseacon-oftwowatchglassesisplacedinatankofcavelens.AfarsightedpersonshouldCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.water.CopyFigure18-17anddrawtheuseaconvexlens.effectofthislensonparallellightraysincidentonthelens.Physics:PrinciplesandProblemsSolutionsManual381
385Chapter18continued33.FocalLengthSupposeyourcameraisChapterAssessmentfocusedonapersonwhois2maway.YounowwanttofocusitonatreethatisfartherConceptMappingaway.Shouldyoumovethelensclosertopage508thefilmorfartheraway?37.CompletethefollowingconceptmapusingCloser;realimagesarealwaysfartherthefollowingterms:inverted,larger,smaller,fromthelensthanthefocalpoint.Thevirtual.fartherawaytheobjectis,theclosertheimageistothefocalpoint.Lenses34.ImageWhyistheimagethatyouobserveconvexconcaveinarefractingtelescopeinverted?Afterthelightrayspassthroughtheobjectivelens,theycross,forminganrealvirtualvirtualimagethatisinverted.Theeyepiecemaintainsthisorientationwhenitusesinverteduprightuprightthisimageasitsobject.35.PrismsWhatarethreebenefitsofhavingsmallerunchangedlargerlargersmallersizeprismsinbinoculars?Theprismsextendthelight’spathlengthMasteringConceptstomakethebinocularsmorecompact,invertlightrayssothattheviewerseespage508anuprightimage,andincreasesepara-38.Howdoestheangleofincidencecomparetionbetweenobjectivelensestoimprovewiththeangleofrefractionwhenalightraythethree-dimensionalview.passesfromairintoglassatanonzeroangle?(18.1)36.CriticalThinkingWhenyouusetheTheangleofincidenceislargerthanCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.highestmagnificationonamicroscope,theangleofrefraction,becauseairhastheimageismuchdarkerthanitisatlowerasmallerindexofrefraction.magnifications.Whataresomepossiblereasonsforthedarkerimage?Whatcould39.Howdoestheangleofincidencecompareyoudotoobtainabrighterimage?withtheangleofrefractionwhenalightrayYouareusingthelightthatstrikesonlyleavesglassandentersairatanonzeroasmallareaoftheobject.Abrighterangle?(18.1)lampcouldbeused.Theangleofincidenceissmallerthantheangleofrefraction,becauseglasshasalargerindexofrefraction.40.Regardingrefraction,whatisthecriticalangle?(18.1)Thetermcriticalanglereferstotheinci-dentanglethatcausestherefractedraytolierightalongtheboundaryofthesubstancewhenarayispassingfromaregionofhigherindexofrefractiontoaregionoflowerindexofrefraction.Iftheincidentangleexceedsthecriticalangle,totalinternalreflectionwilloccur.382SolutionsManualPhysics:PrinciplesandProblems
386Chapter18continued41.AlthoughthelightcomingfromtheSunisAnotherlensisincludedintheopticsrefractedwhilepassingthroughEarth’ssystemoftheprojectortoinverttheatmosphere,thelightisnotseparatedintoimageagain.Asaresult,theimageisitsspectrum.Whatdoesthisindicateuprightcomparedtotheoriginalobject.aboutthespeedsofdifferentcolorsoflighttravelingthroughair?(18.1)47.Describewhyprecisionopticalinstrumentsuseachromaticlenses.(18.2)Thespeedsofthedifferentcolorsoflighttravelingthroughairarethesame.Alllenseshavechromaticaberration,whichmeansdifferentwavelengthsof42.ExplainwhytheMoonlooksredduringalightarebentatslightlydifferentangleslunareclipse.(18.1)neartheiredges.AnachromaticlensisDuringalunareclipse,EarthblockstheacombinationoftwoormorelensesSun’sraysfromtheMoon.However,withdifferentindicesofrefractionthatsunlightrefractingoffEarth’satmos-reducethiseffect.phereisdirectedinwardtowardthe48.Describehowtheeyefocuseslight.(18.3)Moon.Becausebluewavelengthsoflightaredispersedmore,redwave-LightenteringtheeyeisprimarilylengthsoflightreflectofftheMoonfocusedbythecornea.FinefocusingtowardEarth.occurswhenmuscleschangetheshapeofthelens,allowingtheeyetofocuson43.Howdotheshapesofconvexandconcaveeithernearorfarobjects.lensesdiffer?(18.2)49.WhatistheconditioninwhichthefocalConvexlensesarethickeratthecenterlengthoftheeyeistooshorttofocuslightthanattheedges.Concavelensesareontheretina?(18.3)thinnerinthemiddlethanattheedges.nearsightedness44.Locateanddescribethephysicalpropertiesoftheimageproducedbyaconvexlens50.Whattypeofimageisproducedbythewhenanobjectisplacedsomedistanceobjectivelensinarefractingtelescope?beyond2F.(18.2)(18.3)Itisarealimagethatislocatedrealimage,invertedbetweenFand2F,andthatisinvertedandsmallercomparedtotheobject.51.Theprismsinbinocularsincreasethedis-tancebetweentheobjectivelenses.Whyis45.Whatfactor,otherthanthecurvatureofthethisuseful?(18.3)surfacesofalens,determinesthelocationItimprovesthethree-dimensionalview.ofthefocalpointofthelens?(18.2)Theindexofrefractionofthematerial52.Whatisthepurposeofacamera’sreflexfromwhichthelensismadealsodeter-mirror?(18.3)minesthefocus.Thereflexmirrordivertstheimageontoaprismsothatitcanbeviewedbefore46.Toprojectanimagefromamovieprojectortakingaphotograph.Whentheshutterontoascreen,thefilmisplacedbetweenreleasebuttonispressed,thereflexFand2Fofaconverginglens.Thisarrange-mirrormovesoutofthewaysothattheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mentproducesanimagethatisinverted.lensfocusestheimageontothefilmorWhydoesthefilmedsceneappeartobeotherphotodetector.uprightwhenthefilmisviewed?(18.2)Physics:PrinciplesandProblemsSolutionsManual383
387Chapter18continuedApplyingConcepts��1���1.00c,glass/air�sin1.52pages508—509�41.1°53.Whichsubstance,AorB,inFigure18-24hasalargerindexofrefraction?Explain.Airandglasshavethesmallercriticalangleof41.1°.Thecriticalangleforairandwateris48.8°.58.CrackedWindshieldIfyoucrackthewindshieldofyourcar,youwillseeasilverylinealongthecrack.Theglasshasseparatedatthecrack,andthereisairinthecrack.Thesilverylineindicatesthatlightisreflect-ingoffthecrack.Drawaraydiagramtoexplainwhythisoccurs.Whatphenomenondoesthisillustrate?AB■Figure18-24FromoutsideTheangleinsubstanceAissmaller,soCrackithasthelargerindexofrefraction.n�1.054.Alightraystrikestheboundarybetweentwotransparentmedia.Whatistheangleofincidenceforwhichthereisnorefraction?�1��c�1��cAnangleofincidenceof0°allowsthennglassglasslighttogothroughunchanged.Oriftheangleofincidenceisgreaterthanthecriticalanglethereistotalinternalreflection.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.55.Howdoesthespeedoflightchangeastheindexofrefractionincreases?Tothedriver’seyesAstheindexofrefractionofamaterialThisillustrateslightreflectedatanglesincreases,thespeedoflightinthatlargerthanthecriticalangle,ortotalmaterialdecreases.internalreflection.56.Howdoesthesizeofthecriticalangle59.LegendaryMirageAccordingtolegend,changeastheindexofrefractionincreases?ErictheRedsailedfromIcelandanddiscov-ThecriticalangledecreasesastheeredGreenlandafterhehadseentheislandindexofrefractionincreases.inamirage.Describehowthemiragemighthaveoccurred.57.Whichpairofmedia,airandwaterorairEventhoughGreenlandisbelowtheandglass,hasthesmallercriticalangle?horizon,itisvisibleasamiragedueton��1�2therefractionoflight.c�sin��n1�11.00�c,water/air�sin���1.33�48.8°384SolutionsManualPhysics:PrinciplesandProblems
388Chapter18continuedThemagnificationismuchlessinwaterMiragethaninair.Thedifferenceintheindicesofrefractionforwaterandglassismuchlessthanthedifferenceforairandglass.Cold,deW64.Whyistherechromaticaberrationforlightnsearthatgoesthroughalensbutnotforlightamirathatreflectsfromamirror?irChromaticaberrationforlensesisduetoIcelandthedispersionoflight(differentwave-Greenlandlengthsoflighthavedifferentspeedsin60.Aprismbendsvioletlightmorethanitthelensandrefractwithslightlydiffer-bendsredlight.Explain.entangles).Mirrorsreflect,andreflec-tionisindependentofwavelength.Violetlighttravelsslowerinaprismthanredlightdoes.65.Whensubjectedtobrightsunlight,thepupilsofyoureyesaresmallerthanwhentheyare61.RainbowsWhywouldyouneverseearain-subjectedtodimmerlight.Explainwhyyourbowinthesouthernskyifyouwereintheeyescanfocusbetterinbrightlight.northernhemisphere?InwhichdirectionshouldyoulooktoseerainbowsifyouareEyescanfocusbetterinbrightlightinthesouthernhemisphere?becauseraysthatarerefractedintolargeranglesarecutoffbytheiris.YoucanseearainbowonlywhentheTherefore,allraysconvergeataSun’srayscomefrombehindyouatannarrowangle,sothereislesssphericalanglenotgreaterthan42°withthehori-aberration.zon.Whenyouarefacingsouthinthenorthernhemisphere,theSunisnever66.BinocularsTheobjectivelensesinbinocu-behindyouatanangleof42°orless.larsformrealimagesthatareuprightcomparedtotheirobjects.Wherearethe62.SupposethatFigure18-14isredrawnwithimageslocatedrelativetotheeyepiecealensofthesamefocallengthbutalargerlenses?diameter.Explainwhythelocationoftheimagedoesnotchange.WouldtheimageEachsideofthebinocularsislikeabeaffectedinanyway?refractingtelescope.Therefore,theobjectivelensimagemustbebetweenThelocationoftheimagedependsontheeyepiecelensanditsfocalpointtothefocallengthofthelensandthedis-magnifytheimage.tanceoftheobjectfromthelens.Therefore,thelocationoftheimagedoesn’tchange.MasteringProblems18.1RefractionofLight63.Aswimmerusesamagnifyingglasstopages509—510observeasmallobjectonthebottomofaLevel1swimmingpool.Shediscoversthatthemag-67.Arayoflighttravelsfromairintoaliquid,nifyingglassdoesnotmagnifytheobjectCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.asshowninFigure18-25.Therayisinci-verywell.Explainwhythemagnifyingglassdentupontheliquidatanangleof30.0°.isnotfunctioningasitwouldinair.Theangleofrefractionis22.0°.Physics:PrinciplesandProblemsSolutionsManual385
389Chapter18continuedb.Atwhatangledoesthebeamenterthewater?30°ngsin�g�nwsin�wAirn�1gsin�g�w�sin����nLiquidw�1(1.50)(sin25.4°)�sin����1.3322°�28.9°■Figure18-2570.RefertoTable18-1.Usetheindexofrefrac-a.UsingSnell’slaw,calculatetheindexoftionofdiamondtocalculatethespeedofrefractionoftheliquid.lightindiamond.n1sin�1�n2sin�2cn��nv�1sin�1n2�sin�c2v��diamond�ndiamond(1.00)(sin30.0°)���8m/ssin22.0°3.00�10���2.42�1.33�1.24�108m/sb.Comparethecalculatedindexofrefrac-tiontothoseinTable18-1.Whatmight71.RefertoTable18-1.Findthecriticalangletheliquidbe?foradiamondinair.watern��1���2c,diamond/air�sinn168.Lighttravelsfromflintglassintoethanol.Theangleofrefractionintheethanolis�sin�1���1.002.4225.0°.WhatistheangleofincidenceintheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.glass?�24.4°n1sin�1�n2sin�2nLevel2��1�2sin�21�sin��n72.AquariumTankAthicksheetofplastic,1n�1.500,isusedasthesideofanaquari-�1(1.36)(sin25.0°)�sin����umtank.Lightreflectedfromafishinthe1.62waterhasanangleofincidenceof35.0°.�20.8°Atwhatangledoesthelightentertheair?n69.Abeamoflightstrikestheflat,glasssideof1sin�1�n2sin�2awater-filledaquariumatanangleof40.0°nwatersin�water�nplasticsin�plastictothenormal.Forglass,n�1.50.na.Atwhatangledoesthebeamenterthe��1����watersin�waterplastic�sinnglass?plasticn�1��(1.33)(sin35.0°)Asin�A�ngsin�g�sin��1.500n��1���Asin�A�30.57°g�sinngn�1(1.00)(sin40.0°)plasticsin�plastic�nairsin�air�sin����1.50�25.4°386SolutionsManualPhysics:PrinciplesandProblems
390Chapter18continuedn74.Adiamond’sindexofrefractionforred�1plasticsin�plastic�air�sin�����nlight,656nm,is2.410,whilethatforblueairlight,434nm,is2.450.Supposethatwhite�1(1.500)(sin30.57°)�sin�����lightisincidentonthediamondat30.0°.1.00Findtheanglesofrefractionforredand�49.7°bluelight.n73.Swimming-PoolLightsAlightsourceisAsin�A�ndsin�dlocated2.0mbelowthesurfaceofaswim-n��1����Asin�Amingpooland1.5mfromoneedgeofthed�sinndpool,asshowninFigure18-26.ThepoolForredlightisfilledtothetopwithwater.�1(1.00)(sin30.0°)�d�sin����2.410�12.0°Forbluelight2m�1(1.00)(sin30.0°)�d�sin����2.4501.5m�11.8°75.Theindexofrefractionofcrownglassis1.53■Figure18-26forvioletlight,anditis1.51forredlight.a.Atwhatangledoesthelightreachinga.Whatisthespeedofvioletlightintheedgeofthepoolleavethewater?crownglass?��1�1.5mc3.00�108m/si�tan��2.0mv�����n1.53�37°�1.96�108m/sThenfindtheangleinair.b.Whatisthespeedofredlightincrownnglass?Asin�A�nwsin�wc3.00�108m/s��1����nwsin�wv���n��1.51A�sinnA�1.99�108m/s�1(1.33)(sin37°)�sin����1.0076.Thecriticalangleforaspecialglassinairis�53°41.0°.Whatisthecriticalangleiftheglassb.Doesthiscausethelightviewedfromisimmersedinwater?thisangletoappeardeeperorshallowernsin��Athanitactuallyis?c,air�ngsideoppositetan53°���nA1.00sideadjacentn����g�sin��sin41.0°�1.524c,airsideoppositesideadjacent���ntan53°sin��wc,water�n1.5mgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��tan53°n��1���w�1.1m,shallowerc,water�sinng�11.33�sin���1.524�60.8°Physics:PrinciplesandProblemsSolutionsManual387
391Chapter18continuedLevel3c.Determine��.277.Arayoflightinatankofwaterhasannangleofincidenceof55.0°.Whatistheairsin�2��nglasssin�1�angleofrefractioninair?n�1glasssin�1�n�2��sin����n1sin�1�n2sin�2air�1n1sin�1�sin�1����(1.5)(sin32°)�2�sin����n1.002�53°�1(1.33)(sin55.0°)�sin����1.0079.Thespeedoflightinaclearplasticis�sin�1(1.09)1.90�108m/s.ArayoflightstrikestheThevaluesin�plasticatanangleof22.0°.Atwhatangleis2�1.09isnotdefined.Therefore,totalinternalreflectiontherayrefracted?coccurs.n�airsin�air�npsin�pandnp�v,sopc78.TherayoflightshowninFigure18-27isnairsin�air��vsin�ppincidentupona60°-60°-60°glassprism,n�1.5.vpnairsin�airsin���p�cAirAirv�1pnairsin�air�p�sin����c60°�1�45°�1(1.90�108m/s)(1.00)(sin22.0°)�sin������8m/s3.00�10PQ��2�13.7°�2�1�R80.Alightrayentersablockofcrownglass,nglass�1.5asillustratedinFigure18-28.Usearay60°Glass60°Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.diagramtotracethepathoftherayuntilitleavestheglass.■Figure18-27a.UsingSnell’slawofrefraction,determinetheangle,�2,tothenearestdegree.45°nairsin�1�nglasssin�2n��1����airsin�12�sinnglass�11.00sin45°■Figure18-28�sin����1.5nAsin�A�ngsin�g�28°n��1��Asin�Ab.Usingelementarygeometry,determineg�sin��ngthevalueof��.1�1(1.00)(sin45°)��sin����P�90°�28°�62°1.52�Q�180°�62°�60°�58°�28°�Findthecriticalangleforcrownglass.1��90°�58°�32°nsin��Ac�ng388SolutionsManualPhysics:PrinciplesandProblems
392Chapter18continuedn83.Ifanobjectis10.0cmfromaconverging��1���Ac�sinnlensthathasafocallengthof5.00cm,howgfarfromthelenswilltheimagebe?�11.00�sin���1.52111�����fdd�41.1°oidWhenthelightrayintheglassstrikesd�ofi�dthesurfaceata62°angle,totalinternalo�freflectionoccurs.(10.0cm)(5.00cm)����10.0cm�5.00cm�10.0cm62°62°28°28°45°45°Level284.Aconvexlensisneededtoproduceanimagethatis0.75timesthesizeoftheobjectandlocated24cmfromthelensontheotherside.Whatfocallengthshouldbespecified?18.2ConvexandConcaveLensesh�dm��i��ipage510hdooLevel1�d81.Thefocallengthofaconvexlensis17cm.d�io�mAcandleisplaced34cminfrontofthelens.Makearaydiagramtolocatethe�(24cm)����0.75image.�32cmdi�34cm111�����O1Ray1fdodiRay2di�34cmf�dodi�do�diFF(32cm)(24cm)����Horizontalscale:32cm�24cmI11block�2cm�14cm85.Anobjectislocated14.0cmfromaconvex82.Aconverginglenshasafocallengthoflensthathasafocallengthof6.0cm.The25.5cm.Ifitisplaced72.5cmfromanobjectis2.4cmhigh.object,atwhatdistancefromthelenswilla.Drawaraydiagramtodeterminetheloca-theimagebe?tion,size,andorientationoftheimage.111�����fddoiRay1O1dofhi��1.8cmd�Ray2i�ddi�10.5cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.o�fFF(72.5cm)(25.5cm)����72.5cm�25.5cmI1Horizontalscale:�39.3cm1block�1.0cmVerticalscale:Theimageis39.3cmfromthelens.1block�0.4cmPhysics:PrinciplesandProblemsSolutionsManual389
393Chapter18continuedb.Solvetheproblemmathematically.b.Iftheoriginallensisreplacedwithalens111havingtwicethefocallength,whatare�����fddtheimageposition,size,andorientation?oidoffnew�2fdi��do�f�2(6.00cm)(14.0cm)(6.0cm)�����12.0cm14.0cm�6.0cm�10.5cm1��11���fddoih�dm��i��ihododdofnewi,new���do�fnew�dh�ihoi�d����(15.0cm)(12.0cm)o15.0cm�12.0cm��(10.5cm)(2.4cm)�60.0cm���14.0cmh�d��1.8cm,sotheimageism��i��ihdinvertedoo�dh��i,newho86.A3.0-cm-tallobjectisplaced22cminfronti,new�doofaconverginglens.Arealimageisformed�(60.0cm)(3.0cm)11cmfromthelens.Whatisthesizeofthe����15cmimage?��12cmh�dm��i��ihdTheimageisinvertedcomparedtoootheobject.�dh�ihoi�do88.AdiverginglenshasafocallengthofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��(11cm)(3.0cm)15.0cm.Anobjectplacednearitformsa���22cm2.0-cm-highimageatadistanceof5.0cm��1.5cmfromthelens.Theimageis1.5cmtall.a.Whataretheobjectpositionandobjectheight?111�����Level3fddoi87.A3.0-cm-tallobjectisplaced15.0cmindfrontofaconverginglens.Arealimageisd�ifo�dformed10.0cmfromthelens.i�fa.Whatisthefocallengthofthelens?(�5.0cm)(�15.0cm)�����5.0cm�(�15.0cm)111������7.5cmfddoih�ddiif��odim����hddooo�di(15.0cm)(10.0cm)�dohi����h�15.0cm�10.0cmo�di�6.00cm�(7.5cm)(2.0cm)�����5.0cm�3.0cm390SolutionsManualPhysics:PrinciplesandProblems
394Chapter18continuedb.Thediverginglensisnowreplacedbyab.A1000.0-mmlensisfocusedonanconverginglenswiththesamefocalobject125maway.Whatistheimagelength.Whataretheimageposition,position?height,andorientation?Isitavirtual111�����imageorarealimage?fddiofnew��fdofSodi��d��(�15.0cm)o�f(125m)(1.0000m)�15.0cm����125m�1.00m111�1.01m�1.01�103mm�����fddnewoi,newd90.EyeglassesToclearlyreadabook25cmd��ofnewi,new�daway,afarsightedgirlneedstheimagetobeo�fnew45cmfromhereyes.Whatfocallengthis(7.5cm)(15cm)���neededforthelensesinhereyeglasses?7.5cm�15cm111��15cm�����fddiohi�didm����odihdSof��oodo�di�dh��i,newho(25cm)(�45cm)i,new�d����o25cm�(�45cm)�(�15cm)(3.0cm)�56cm����7.5cm�6.0cmLevel2Thisisavirtualimagethatisupright91.CopyMachineTheconvexlensofacopycomparedtotheobject.machinehasafocallengthof25.0cm.Alettertobecopiedisplaced40.0cmfromthelens.18.3ApplicationsofLensesa.Howfarfromthelensisthecopypages510–511paper?Level111189.CameraLensesCameralensesare�����fddiodescribedintermsoftheirfocallength.dA50.0-mmlenshasafocallengthofd�ofi�d50.0mm.o�fa.Acamerawitha50.0-mmlensis����(40.0cm)(25.0cm)40.0cm�25.0cmfocusedonanobject3.0maway.Whatistheimageposition?�66.7cm111b.Howmuchlargerwillthecopybe?�����fddioh�d�i��iSoddofhodoi��Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.do�f�d�(66.7cm)(hh�iho��o)(3.0�103mm)(50.0mm)i��do40.0cm����3.0�103mm�50.0mm��1.67ho�51mmThecopyisenlargedandinverted.Physics:PrinciplesandProblemsSolutionsManual391
395Chapter18continued92.CameraAcameralenswithafocallength94.TelescopeTheopticalsystemofatoyof35mmisusedtophotographadistantrefractingtelescopeconsistsofaconvergingobject.Howfarfromthelensistherealobjectivelenswithafocallengthofimageoftheobject?Explain.20.0cm,located25.0cmfromaconverging35mm;foradistantobject,deyepiecelenswithafocallengthofocanbeconsideredat,thus1/d4.05cm.Thetelescopeisusedtoviewaoiszero.Accordingtothethinlensequation,10.0-cm-highobject,located425cmfromdtheobjectivelens.i�f.a.Whataretheimageposition,height,Level3andorientationasformedbytheobjec-93.MicroscopeAslideofanonioncellistivelens?Isthisarealorvirtualimage?placed12mmfromtheobjectivelensof1��11���amicroscope.Thefocallengthofthefdodiobjectivelensis10.0mm.dd�ofa.Howfarfromthelensistheimagei�do�fformed?(425cm)(20.0cm)����1��11425cm�20.0cm���fddio�21.0cmdSod�ofhi�di�dm����io�fhdoo(12mm)(10.0mm)�����d12mm�10.0mmh�ihoi�d1mmo�6.0�10�(21.0cm)(10.0cm)b.Whatisthemagnificationofthisimage?����425cm�di�6.0�101mmm�����0.494cmo��d12mm��5.0oThisisarealimagethatisinvertedCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.Therealimageformedislocatedcomparedtotheobject.10.0mmbeneaththeeyepiecelens.Ifthefocallengthoftheeyepieceisb.Theobjectivelensimagebecomesthe20.0mm,wheredoesthefinalimageobjectfortheeyepiecelens.Whatareappear?theimageposition,height,andorienta-tionthatapersonseeswhenlooking111�����fddintothetelescope?Isthisarealoriovirtualimage?dd�ofdi�do,new�25.0cm�dio�f(10.0mm)(20.0mm)�25.0cm�21.0cm����10.0mm�20.0mm�4.0cm��20.0mm,or20.0mmbeneaththeeyepiece�1��1��1fddnewo,newi,newd.Whatisthefinalmagnificationofthisdcompoundsystem?d��o,newfnewi,new�d�do,new�fnewi�(�20.0mm)m���e��do10.0mm�2.00(4.0cm)(4.05cm)����4.0cm�4.05cmmtotal�mome�(�5.0)(2.00)2cm��3.2�10��1.0�101392SolutionsManualPhysics:PrinciplesandProblems
396Chapter18continuedh97.A3.0-cm-tallobjectisplaced20cminfronto,new�hiofaconverginglens.Arealimageisformed��0.494cm10cmfromthelens.Whatisthefocalh�dlengthofthelens?m��i��ihodo111������dfdodih��i,newho,newi,new�ddo,newodif���(�3.2�102cm)(�0.494cm)do�di�����4.0cm(20cm)(10cm)���1cm20cm�10cm��4.0�10�7cmThisisavirtualimagethatisinvert-edcomparedtotheobject.c.WhatisthemagnificationoftheLevel298.Deriven�sin�telescope?1/sin�2fromthegeneralformofSnell’slawofrefraction,hm��i,newn1sin�1�n2sin�2.Stateanyassumptionshoandrestrictions.�4.0�101cmTheangleofincidencemustbeinair.If���10.0cmweletsubstance1beair,thenn1���4.01.000.Letn2�n.Therefore,nMixedReview1sin�1�n2sin�2pages511—512sin�1�nsin�2Level1sin��1�n95.Ablockofglasshasacriticalangleof45.0°.sin�2Whatisitsindexofrefraction?99.AstronomyHowmanymoreminutesnsin��2wouldittakelightfromtheSuntoreachc�n1Earthifthespacebetweenthemwerefilledn2withwaterratherthanavacuum?TheSunn�1�sin�c,n2�1.00forairis1.5�108kmfromEarth.1.00Timethroughvacuumn��1�sin45.0°d(1.5�108km)(1000m/1km)t��������1.41c3.00�108m/s�5.0�102s96.Findthespeedoflightinantimonytrioxideifithasanindexofrefractionof2.35.Speedthroughwatercc3.00�108m/sn��v�����vn1.33c�2.26�108m/sv��nTimethroughwater3.00�108m/s8km)(1000m/1km)���d(1.5�10Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.2.35t�������8m/sv2.26�10�1.28�108m/s�660s�t�660s�500s�160s�(160s)(1min/60s)�2.7minPhysics:PrinciplesandProblemsSolutionsManual393
397Chapter18continued100.Whatisthefocallengthofthelensesinb.Atwhatdepthdoesthebottomoftheyoureyeswhenyoureadabookthatistankappeartobeifyoulookintothe35.0cmfromthem?Thedistancefromwater?Dividethisapparentdepthintoeachlenstotheretinais0.19mm.thetruedepthandcompareittothe111indexofrefraction.�����fdodiUsingrighttrianglegeometry,(actu-dodialdepth)(tan�1)�(apparentf��do�didepth)(tan�2)(350mm)(0.19mm)tan5.0°����apparentdepth�(12cm)���350mm�0.19mmtan6.7°�0.19mm�8.9cmTherefractedraysappeartointer-sect8.9cmbelowthesurface;thisLevel3istheapparentdepth.101.ApparentDepthSunlightreflectsdiffu-apparentdepth8.9cmsivelyoffthebottomofanaquarium.�����0.74truedepth12cmFigure18-29showstwoofthemanylightnair1.0raysthatwouldreflectdiffusivelyfromaAlso,����0.75n1.33pointoffthebottomofthetankandtravelwatertothesurface.ThelightraysrefractintotheTherefore,airasshown.Thereddashedlineextendingapparentdepthnair����backfromtherefractedlightrayisasighttruedepthnwaterlinethatintersectswiththeverticalrayat102.Itisimpossibletoseethroughadjacentsidesthelocationwhereanobserverwouldseeofasquareblockofglasswithanindexoftheimageofthebottomofthetank.refractionof1.5.Thesideadjacenttothesidethatanobserverislookingthroughacts�2asamirror.Figure18-30showsthelimitingcasefortheadjacentsidetonotactlikeaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.mirror.Useyourknowledgeofgeometryandcriticalanglestoshowthatthisrayconfigu-rationisnotachievablewhennglass�1.5.12cmnglass�1.55.0°�1�90°■Figure18-29a.ComputethedirectionthattheAir�2refractedraywilltravelabovethesurfaceofthewater.n�1�1sin�1�n2sin�2n��1����1sin�12�sinnAir2�2��90°�1(1.33)(sin5.0°)�sin����1.0■Figure18-30�6.7°Thelightrayenterstheglassatanangle�1andisrefractedtoanangle�2.394SolutionsManualPhysics:PrinciplesandProblems
398Chapter18continuedn��1����Asin�AThinkingCritically2�sinngpage512�1(1.00)(sin90°)104.RecognizeSpatialRelationshipsWhite�sin����1.5lighttravelingthroughair(n�1.0003)�42°entersaslabofglass,incidentatexactly45°.Fordenseflintglass,n�1.7708forTherefore,�1��48°.bluelight(��435.8nm)andn�1.7273Butthecriticalangleforglassisforredlight(��643.8nm).Whatisthenangulardispersionoftheredandblue��1���Ac�sinnlight?gFindtheanglesofrefractionforred�11.00�sin���andbluelight,andfindthedifference1.5inthoseanglesindegrees.�42°UseSnell’slaw,nBecause�1sin�1�n2sin�2.1���c,thelightreflectsbackintotheglassandonecannotThus,��1����n1sin�1seeoutofanadjacentside.2�sinn2Forredlight103.BankTellerWindowA25-mm-thicksheetofplastic,n�1.5,isusedinabankteller’s��1��(1.0003)(sin45.000���°)2�sin1.7273window.Arayoflightstrikesthesheetatanangleof45°.Therayleavesthesheetat�24.173°45°,butatadifferentlocation.UsearayForbluelightdiagramtofindthedistancebetweenthe�1(1.0003)(sin45.000°)raythatleavesandtheonethatwouldhave�2�sin�����1.7708leftiftheplasticwerenotthere.�23.543°8mmDifference24.173°�23.543°�0.630°105.CompareandContrastFindthecriticalangleforice(n�1.31).Inaverycold25mmworld,wouldfiber-opticcablesmadeofmiceorthosemadeofglassdoabetterjobm8ofkeepinglightinsidethecable?Explain.nsin��airc�nice45°��1���nair�1�1.00c�sinn�sin��1.31�49.8°iceIncomparison,thecriticalanglefor28°glass,n�1.54,is40.5°.Thelargercrit-icalanglemeansthatfewerrayswould45°betotallyinternallyreflectedinaniceCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.corethaninaglasscore.Thus,theywouldnotbeabletotransmitasmuchlight.Fiberopticcablesmadeofglasswouldworkbetter.Physics:PrinciplesandProblemsSolutionsManual395
399Chapter18continued106.RecognizeCauseandEffectYourlabWritinginPhysicspartnerusedaconvexlenstoproduceanpage512imagewithdi�25cmandhi�4.0cm.109.Theprocessofaccommodation,wherebyYouareexaminingaconcavelenswithamusclessurroundingthelensintheeyefocallengthof�15cm.Youplacethecontractorrelaxtoenabletheeyetoconcavelensbetweentheconvexlensandfocusoncloseordistantobjects,variesfortheoriginalimage,10cmfromtheimage.differentspecies.InvestigatethiseffectToyoursurprise,youseearealimageonfordifferentanimals.Prepareareportthewallthatislargerthantheobject.Youfortheclassshowinghowthisfinefocus-aretoldthattheimagefromtheconvexingisaccomplishedfordifferenteyelensisnowtheobjectfortheconcavelens,mechanisms.andbecauseitisontheoppositesideofAnswerswillvarydependingonthetheconcavelens,itisavirtualobject.Useanimalsselectedbythestudents.thesehintstofindthenewimagepositionandimageheightandtopredictwhether110.Investigatethelenssystemusedinanopticaltheconcavelenschangedtheorientationinstrumentsuchasanoverheadprojectororoftheoriginalimage.aparticularcameraortelescope.PrepareaThenewdo��10cm.Thus,graphicsdisplayfortheclassexplaininghowfdo(�15cm)(�10cm)theinstrumentformsimages.d����i��d�10cm�(�15cm)Answerswillvary.Studentsmayfindo�f��30cmthatitisnecessarytosimplifytheirchosensystemforexplanation�di�30cmm������3purposes.d�10cmohi�mho�(3)(4.0cm)�10cmCumulativeReviewTheimageorientationisnotchanged.page512111.Ifyoudropa2.0kgbagofleadshotfromaheightof1.5m,youcouldassumeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.107.DefineOperationallyNameanddescribetheeffectthatcausestherainbow-coloredthathalfofthepotentialenergywillbefringecommonlyseenattheedgesofaconvertedintothermalenergyinthelead.spotofwhitelightfromaslideorTheotherhalfwouldgotothermalenergyoverheadprojector.inthefloor.Howmanytimeswouldyouhavetodropthebagtoheatitby10°C?Thelightthatpassesthroughalens(Chapter12)neartheedgesofthelensisslightlydispersed,sincetheedgesofalensPE�mghresembleaprismandrefractdifferent�(2.0kg)(9.80m/s2)(1.5m)wavelengthsoflightatslightlydifferent�29.4Jangles.TheresultisthatwhitelightisToheatthebagdispersedintoitsspectrum.Theeffectiscalledchromaticaberration.Q�mC�T�(2.0kg)(130J/kg°C)(10°C)108.ThinkCriticallyAlensisusedtoproject�2600Jtheimageofanobjectontoascreen.Q2600JSupposethatyoucovertherighthalfofN��11thelens.Whatwillhappentotheimage?��PE��(29.4J)22Itwillgetdimmer,becausefewerlight�180timesrayswillconverge,butyouwillseeacompleteimage.396SolutionsManualPhysics:PrinciplesandProblems
400Chapter18continued112.Ablacksmithputsanironhooportireonb.HowwouldtheilluminanceonyourtheouterrimofawoodencarriagewheelhandfromtheSunatthenewpositionbyheatingthehoopsothatitexpandstoacomparetowhatitwaswhenyouwerediametergreaterthanthewoodenwheel.standingonitssurface?(Forsimplicity,Whenthehoopcools,itcontractstoholdassumethattheSunisapointsourcetheriminplace.Ifablacksmithhasaatbothpositions.)woodenwheelwitha1.0000-mdiameter11�6Itis�����1�10andwantstoputarimwitha0.9950-m100021,000,000diameteronthewheel,whatisthethevalueitwasoriginally.minimumtemperaturechangetheironc.Comparetheeffectofdistanceuponmustexperience?(��6/°C)iron�12�10thegravitationalforceandilluminance.(Chapter13)Theybothfollowtheinversesquare�L��ironL�TwhereListhediameterlawofdistance.oftheironhoop.Wewant�Lgreaterthan0.0050m.115.Beautician’sMirrorThenoseofaTherefore,customerwhoistryingsomefacepowder�Lis3.00-cmhighandislocated6.00cmin�T���ironLfrontofaconcavemirrorhavinga14.0-cmfocallength.Findtheimagepositionand0.0050����(12�10�6/°C)(0.9950m)heightofthecustomer’snosebymeansofthefollowing.(Chapter17)�420°Ca.araydiagramdrawntoscaleActuallyhewouldheatitmuchhottertogiveroomtofitoverthewheeleasily.O1I1113.Acarsoundsitshornasitapproachesapedestrianinacrosswalk.WhatdoesthepedestrianhearasthecarbrakestoallowHorizontalscale:hi�5.25cmhimtocrossthestreet?(Chapter15)1block�1.0cmdi��10.5cmVerticalscale:Thepitchofthehornheardbythe1block�1.0cmpedestrianwilldecreaseasthecarslowsdown.b.themirrorandmagnificationequations111114.Supposethatyoucouldstandonthe�����fdodisurfaceoftheSunandweighyourself.Alsosupposethatyoucouldmeasurethedofd�i�dilluminanceonyourhandfromtheSun’so�fvisiblespectrumproducedatthatposition.(6.00cm)(14.0cm)����Next,imagineyourselftravelingtoa6.00cm�14.0cmposition1000timesfartherawayfromthe��10.5cmcenteroftheSunasyouwerewhenh�dstandingonitssurface.(Chapter16)m��i��ihdooa.HowwouldtheforceofgravityonyoufromtheSunatthenewpositioncom-�dihoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.hi��paretowhatitwasatthesurface?doItis�1���1�1�10�6�(�10.5cm)(3.00cm)(1000)21,000,000����6.00cmthevalueitwasoriginally.�5.25cmPhysics:PrinciplesandProblemsSolutionsManual397
401Chapter18continued4.IfyouwanttheangleofrefractionfortheChallengeProblemlightrayinwatertobethesameasitispage501forair,whatshouldthenewangleofinci-Aslightenterstheeye,itfirstencountersthedencebe?air/corneainterface.Considerarayoflightthatn1sin�1�n2sin�2strikestheinterfacebetweentheairandaper-nson’scorneaatanangleof30.0°tothenormal.��1���2sin�21�sinnTheindexofrefractionofthecorneaisapproxi-1mately1.4.(1.4)(sin21°)�sin�1����1.UseSnell’slawtocalculatetheangleof1.33refraction.�22°n1sin�1�n2sin�2nAirCornea��1���1sin�12�sinn2(1.0)(sin30.0°)�sin�1����1.430.0°�21°�22.Whatwouldtheangleofrefractionbeifthepersonwasswimmingunderwater?n1sin�1�n2sin�2n��1���1sin�12�sinn2(1.33)(sin30.0°)�sin�1����1.4�28°Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3.Istherefractiongreaterinairorinwater?Doesthismeanthatobjectsunderwaterseemcloserormoredistantthantheywouldinair?Refractionisgreaterinairbecausetheangletothenormalissmaller.Objectsseemcloserinwater.398SolutionsManualPhysics:PrinciplesandProblems
402CHAPTERInterferenceand19Diffraction4.Yellow-orangelightwithawavelengthofPracticeProblems596nmpassesthroughtwoslitsthatare19.1Interferenceseparatedby2.25�10�5mandmakesanpages515–523interferencepatternonascreen.Ifthedis-tancefromthecentrallinetothefirst-orderpage519yellowbandis2.00�10�2m,howfaristhe1.Violetlightfallsontwoslitsseparatedby1.90�10�5m.Afirst-orderbrightbandscreenfromtheslits?appears13.2mmfromthecentralbrightxd����Lbandonascreen0.600mfromtheslits.Whatis�?L��xd��xd�����2�5L(2.00�10m)(2.25�10m)������9596�10m(13.2�10�3m)(1.90�10�5m)�����0.600m�0.755m�418nmpage5222.Yellow-orangelightfromasodiumlampof5.InthesituationinExampleProblem2,wavelength596nmisaimedattwoslitsthatareseparatedby1.90�10�5m.Whatwhatwouldbethethinnestfilmthatwouldcreateareflectedred(��635nm)band?isthedistancefromthecentralbandtothefirst-orderyellowbandifthescreenis1�2t��m������2n0.600mfromtheslits?oil�LForthethinnestfilm,m�0.x���d1�t������(13.2�10�3m)(1.90�10�5m)4noil�����0.600m635nm����1.88�10�2m�18.8mm(4)(1.45)�109nm3.Inadouble-slitexperiment,physicsstu-dentsusealaserwith��632.8nm.A6.Aglasslenshasanonreflectivecoatingstudentplacesthescreen1.000mfromtheplacedonit.Ifafilmofmagnesiumslitsandfindsthefirst-orderbrightbandfluoride,n�1.38,isplacedontheglass,65.5mmfromthecentralline.Whatisthen�1.52,howthickshouldthelayerbetoslitseparation?keepyellow-greenlightfrombeingreflected?���xd�Becausenfilm�nair,thereisaphaseLinversiononthefirstreflection.�Ld���BecausenCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.xglass�nfilm,thereisaphase(632.8�10�9m)(1.000m)inversiononthesecondreflection.�����65.5�10�3mFordestructiveinterferencetokeepyellow-greenfrombeingreflected:�9.66�10�6m�9.66�m1�2t��m�����2nfilmPhysics:PrinciplesandProblemsSolutionsManual399
403Chapter19continuedForthethinnestfilm,m�0.Forthethinnestfilm,m�1.1��t������t���4nfilm2nfilm555nm521nm������(4)(1.38)(2)(1.33)�101nm�196nm7.Asiliconsolarcellhasanonreflective9.Whatisthethinnestsoapfilm(n�1.33)coatingplacedonit.Ifafilmofsodiumforwhichlightofwavelength521nmwillmonoxide,n�1.45,isplacedonthesili-constructivelyinterferewithitself?con,n�3.5,howthickshouldthelayerbeForconstructiveinterferencetokeepyellow-greenlight(��555nm)1�frombeingreflected?2t��m��2���nfilmBecausenfilm�nair,thereisaphaseForthethinnestfilm,m�0.inversiononthefirstreflection.1�Becausent������silicon�nfilm,thereisaphase4nfilminversiononthesecondreflection.521nmFordestructiveinterferencetokeep���(4)(1.33)yellow-greenfrombeingreflected:�97.9nm1�2t��m�����2nfilmForthethinnestfilm,m�0.SectionReview1�t������19.1Interference4nfilmpages515–523555nm���page523(4)(1.45)10.FilmThicknessLucienisblowingbubblesCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�95.7nmandholdsthebubblewandupsothatasoapfilmissuspendedverticallyintheair.Whatis8.Youcanobservethin-filminterferencebythesecondthinnestwidthofthesoapfilmatdippingabubblewandintosomebubblewhichhecouldexpecttoseeabrightstripeifsolutionandholdingthewandintheair.thelightilluminatingthefilmhasawave-Whatisthethicknessofthethinnestsoaplengthof575nm?Assumethesoapsolutionfilmatwhichyouwouldseeablackstripehasanindexofrefractionof1.33.ifthelightilluminatingthefilmhasawavelengthof521nm?Usen�1.33.Thereisonephaseinversion,soconstructiveinterferencewillbewhenBecausenfilm�nair,thereisaphase1�changeonthefirstreflection.Because2t��m�����2nfilmnair�nfilm,thereisnophasechangeonForthesecondthinnestthickness,m�1.thesecondreflection.Fordestructiveinterferencetogeta�3��t����4nblackstripefilmm�(3)(575nm)2t������n(4)(1.33)film�324nm400SolutionsManualPhysics:PrinciplesandProblems
404Chapter19continued11.BrightandDarkPatternsTwoverynar-reflection.Forconstructiveinterfer-rowslitsarecutclosetoeachotherinalargeencetoreflectyellow-greenlight:pieceofcardboard.Theyareilluminatedby1�monochromaticredlight.Asheetofwhite2t��m�����2nfilmpaperisplacedfarfromtheslits,andapat-Forthethinnestfilm,m�0.ternofbrightanddarkbandsisseenonthepaper.Describehowawavebehaveswhenit1�colort������4nencountersaslit,andexplainwhysomefilmregionsarebrightwhileothersaredark.555nm���Whenawaveencountersaslit,the(4)(1.83)wavebends.Lightisdiffractedbythe�75.8nmslits.Lightfromoneslitinterfereswithb.Unfortunately,afilmthisthincannotlightfromtheother.Ifinterferenceisbemanufactured.Whatisthenext-constructive,thereisabrightband;ifthinnestfilmthatwillproducethedestructive,theregionisdark.sameeffect?Forthenextthinnestfilm,m�1.12.InterferencePatternsSketchthepattern�describedinproblem11.3colort������4nfilmRepeatsRepeatsandfadesandfades(3)(555nm)���(4)(1.83)�227nmBlackRedBlackRedBlackRedBlack15.CriticalThinkingTheequationforwave-13.InterferencePatternsSketchwhathap-lengthfromadouble-slitexperimentusespenstothepatterninproblem11whenthethesimplificationthat�issmallsothatredlightisreplacedbybluelight.sin��tan�.UptowhatangleisthisaRepeatsRepeatsgoodapproximationwhenyourdatahasandfadesandfadestwosignificantfigures?Wouldthemaxi-mumangleforavalidapproximationRedRedRedincreaseordecreaseasyouincreasetheBlackBlackBlackBlackprecisionofyouranglemeasurement?sin��tan�totwosignificantdigitsupBlueBlackBlueBlackBlueBlackBlueBlackBlueto9.9°.Anincreaseintheprecisionofthemeasurementreducesthisangleto2.99°.Thelightbandsbecomemorecloselyspaced.PracticeProblems14.FilmThicknessAplasticreflectingfilm19.2Diffraction(n�1.83)isplacedonanautoglasspages524–531window(n�1.52).page526a.Whatisthethinnestfilmthatwill16.Monochromaticgreenlightofwavelengthreflectyellow-greenlight?546nmfallsonasingleslitwithawidthCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Becausenfilm�nair,thereisaphaseof0.095mm.Theslitislocated75cmfromchangeonthefirstreflection.ascreen.HowwidewillthecentralbrightBecausenglass�nfilm,thereisnotbandbe?aphasechangeonthesecondPhysics:PrinciplesandProblemsSolutionsManual401
405Chapter19continuedx20.Whitelightfallsonasingleslitthatisminw���0.050mmwide.Ascreenisplaced1.00mLaway.Astudentfirstputsablue-violetfilter�Lxmin��w�(��441nm)overtheslit,thenaredfilter(5.46�10�7m)(0.75m)(��622nm).Thestudentmeasuresthe����9.5�10�5mwidthofthecentralbrightband.a.Whichfilterproducedthewiderband?�4.3mmRed,becausecentralpeakwidthis17.Yellowlightwithawavelengthof589nmproportionaltowavelength.passesthroughaslitofwidth0.110mmandb.Calculatethewidthofthecentralbrightmakesapatternonascreen.Ifthewidthofbandforeachofthetwofilters.thecentralbrightbandis2.60�10�2m,2�Lhowfarisitfromtheslitstothescreen?2x1��w�2x�2��LForblue,1�w2(4.41�10�7m)(1.00m)(2x1)w2x1����5.0�10�5mL��2��18mm(2.60�10�2m)(0.110�10�3m)�����Forred,(2)(589�10�9m)2(6.22�10�7m)(1.00m)2x����2.43m1�5.0�10�5m�25mm18.LightfromaHe-Nelaser(��632.8nm)fallsonaslitofunknownwidth.Apatternisformedonascreen1.15maway,onpage529whichthecentralbrightbandis15mm21.Whitelightshinesthroughagratingontoawide.Howwideistheslit?screen.Describethepatternthatisproduced.2x�2��LAfullspectrumofcolorisseen.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1�wBecauseofthevarietyofwavelengths,2�Ldarkfringesofonewavelengthwouldw���2x1befilledbybrightfringesofanother(2)(632.8�10�9m)(1.15m)color.�����15�10�3m22.Ifbluelightofwavelength434nmshines�9.7�10�5monadiffractiongratingandthespacing�97�moftheresultinglinesonascreenthatis1.05mawayis0.55m,whatisthespacing19.Yellowlightfallsonasingleslit0.0295mmbetweentheslitsinthegrating?wide.Onascreenthatis60.0cmaway,the��dsin�centralbrightbandis24.0mmwide.Whatisthewavelengthofthelight?d����where��tan�1��x��sin�L2�L2x���1�w���sin�tan�1��x���(2x)wL1����2L434�10�9���(24.0�10�3m)(0.0295�10�3m)sin�tan�1��0.55�m�������(2)(60.0�10�2m)1.05m�5.90�102nm�9.4�10–7m402SolutionsManualPhysics:PrinciplesandProblems
406Chapter19continued23.Adiffractiongratingwithslitsseparatedby8.60�10�7misilluminatedbyvioletlightSectionReviewwithawavelengthof421nm.Ifthescreenis19.2Diffraction80.0cmfromthegrating,whatisthesepa-pages524–531rationofthelinesinthediffractionpattern?page531��dsin�26.DistanceBetweenFirst-OrderDark�BandsMonochromaticgreenlightofwave-sin����dlength546nmfallsonasingleslitofwidthx0.080mm.Theslitislocated68.0cmfromtan����Lascreen.Whatistheseparationofthefirstx�Ltan�darkbandsoneachsideofthecentralbrightband?�1��Ltan�sin�����d2�L2x��min�w�1421�10�9m�(0.800m)�tan�sin���8.60�10�7m���(2)(546�10�9m)(68.0�10�2m)�����0.080�10�3m�0.449m�9.3mm24.BluelightshinesontheDVDinExampleProblem3.Ifthedotsproducedona27.DiffractionPatternsManynarrowslitsarewallthatis0.65mawayareseparatedclosetoeachotherandequallyspacedinaby58.0cm,whatisthewavelengthoflargepieceofcardboard.Theyareillumi-thelight?natedbymonochromaticredlight.Asheetofwhitepaperisplacedfarfromtheslits,�1x��dsin��dsin�tan�����andapatternofbrightanddarkbandsisLvisibleonthepaper.Sketchthepatternthat�(7.41�10�7m)sintan�1�0.58m������wouldbeseenonthescreen.0.65m�490nmPatternPatternrepeatsrepeats25.Lightofwavelength632nmpassesthroughadiffractiongratingandcreatesapatternonascreenthatis0.55maway.Ifthefirstbrightbandis5.6cmfromthecentralbrightband,howmanyslitspercentimeterdoesthegratinghave?Brightredlines��dsin�1Thereisoneslitperdistanced,so��Bandspacingisexactlythesameasindgivesslitspercentimeter.thepatternproducedbythetwoslits,��butnowlightbandsaremuchthinnerd������sin�sin�tan�1��x���andseparatedbywiderdarkbands.L632�10�9m28.LineSpacingYoushinearedlaserlight���throughonediffractiongratingandformasin�tan�1��0.05�6m��Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.0.55mpatternofreddotsonascreen.Thenyou�6.2�10–6m�6.2�10–4cmsubstituteaseconddiffractiongratingforthefirstone,formingadifferentpattern.1slit3slits/cmThedotsproducedbythefirstgratingare���1.6�106.2�10–4cmspreadoutmorethanthoseproducedbythesecond.WhichgratinghasmorelinesPhysics:PrinciplesandProblemsSolutionsManual403
407Chapter19continuedpermillimeter?Completethefollowingconceptmapusing�,L,anddtoindicatehowyoucouldvaryxd����,sothegreaterthedotspacings,themtoproducetheindicatedchangeintheLx,thenarrowertheslitspacing,d,andspacingbetweenadjacentbrightbands,x.thusmorelinespermillimeter.xd29.RayleighCriterionThebrighteststarinthe���L�winterskyinthenorthernhemisphereisSirius.Inreality,Siriusisasystemoftwotoincreasex,todecreasex,starsthatorbiteachother.IftheHubbleSpaceTelescope(diameter2.4m)ispointedattheSiriussystem,whichis8.44light-yearsfromincreasedecreaseincreasedecreaseEarth,whatistheminimumseparationtherewouldneedtobebetweenthestarsinorder�Ldd�Lforthetelescopetobeabletoresolvethem?Assumethattheaveragelightcomingfromthestarshasawavelengthof550nm.MasteringConcepts1.22�Lobjpage536x��obj�D32.Whyisitimportantthatmonochromaticlight1.22(330�10�9m)(7.99�1016m)wasusedtomaketheinterferencepatternin�����2.4mYoung’sinterferenceexperiment?(19.1)�2.2�1010mWhenmonochromaticlightisused,yougetasharpinterferencepattern;ifyou30.CriticalThinkingYouareshownausewhitelight,yougetsetsofcoloredspectrometer,butdonotknowwhetherbands.itproducesitsspectrumwithaprismoragrating.Bylookingatawhite-light33.Explainwhythepositionofthecentralspectrum,howcouldyoutell?brightbandofadouble-slitinterferenceCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.patterncannotbeusedtodeterminetheDetermineifthevioletortheredendofwavelengthofthelightwaves.(19.1)thespectrummakesthelargestanglewiththedirectionofthebeamofinci-Allwavelengthsproducethelineinthedentwhitelight.Aprismbendsthevio-sameplace.letendofthespectrumthemost,whereasagratingdiffractsredwave-34.Describehowyoucoulduselightofalengthsthemost.knownwave-lengthtofindthedistancebetweentwoslits.(19.1)Letthelightfallonthedoubleslit,andChapterAssessmentlettheinterferencepatternfallonasheetofpaper.MeasurethespacingsConceptMappingbetweenthebrightbands,x,andusepage536�Ltheequationd���.31.Monochromaticlightofwavelength�xilluminatestwoslitsinaYoung’sdouble-slit35.Describeinyourownwordswhathappensinexperimentsetupthatareseparatedbyathin-filminterferencewhenadarkbandisdistance,d.Apatternisprojectedontoaproducedbylightshiningonasoapfilmsus-screenadistance,L,awayfromtheslits.pendedinair.Makesureyouincludeinyourexplanationhowthewavelengthofthelightandthicknessofthefilmarerelated.(19.1)404SolutionsManualPhysics:PrinciplesandProblems
408Chapter19continuedWhenthelightstrikesthefrontofthe39.Foragivendiffractiongrating,whichcolorfilm,somereflectsoffthissurfaceandofvisiblelightproducesabrightlineclosestsomepassesthroughthefilmandtothecentralbrightband?(19.2)reflectsoffthebacksurfaceofthefilm.violetlight,thecolorwiththesmallestWhenlightreflectsoffamediumwithawavelengthhigherindexofrefraction,itundergoesaphaseshiftofone-halfwavelength;ApplyingConceptsthishappenstothelightthatinitiallypage536reflects.Inorderforadarkbandtobe40.Foreachofthefollowingexamples,indicateproduced,thetwolightraysmustbewhetherthecolorisproducedbythin-filmone-halfwavelengthoutofphase.Iftheinterference,refraction,orthepresenceofthicknessofthefilmissuchthattheraypigments.reflectingoffthebacksurfacegoesa.soapbubblesthroughawholenumberofcycleswhilepassingthroughthefilm,thelightraysinterferencearrivingatyoureyewillbeoutofphaseb.rosepetalsanddestructivelyinterfere.Rememberpigmentsthatthewavelengthisalteredbythec.oilfilmsindexofrefractionofthefilm,sothatthethicknessofthefilmmustequalainterferencemultipleofhalfawavelengthofthed.arainbowlight,dividedbythefilm’sindexofrefractionrefraction.41.Howcanyoutellwhetherapatternispro-36.Whitelightshinesthroughadiffractionducedbyasingleslitoradoubleslit?grating.AretheresultingredlinesspacedAdouble-slitinterferencepatterncon-morecloselyorfartherapartthanthesistsofequallyspacedlinesofalmostresultingvioletlines?Why?(19.2)equalbrightness.Asingle-slitdiffrac-Thespacingisdirectlyproportionaltotionpatternhasabright,broadcentralthewavelength,andbecauseredlightbandanddimmersidebands.hasalongerwavelengththanviolet,theredlineswillbespacedfartherapart42.Describethechangesinasingle-slitthanthevioletlines.diffractionpatternasthewidthoftheslitisdecreased.37.WhydodiffractiongratingshavelargeThebandsgetwideranddimmer.numbersofslits?Whyaretheseslitssoclosetogether?(19.2)43.ScienceFairAtasciencefair,oneexhibi-Thelargenumberofgroovesindiffrac-tionisaverylargesoapfilmthathasafairlytiongratingsincreasestheintensityofconsistentwidth.Itisilluminatedbyalightthediffractionpatterns.Thegroovesarewithawavelengthof432nm,andnearlytheclosetogether,producingsharperentiresurfaceappearstobealovelyshadeofimagesoflight.purple.Whatwouldyouseeinthefollowingsituations?38.Whywouldatelescopewithasmalldiam-a.thefilmthicknesswasdoubledCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.eternotbeabletoresolvetheimagesofcompletedestructiveinterferencetwocloselyspacedstars?(19.2)b.thefilmthicknesswasincreasedbyhalfSmallapertureshavelargediffractionawavelengthoftheilluminatinglightpatternsthatlimitresolution.completeconstructiveinterferencePhysics:PrinciplesandProblemsSolutionsManual405
409Chapter19continuedc.thefilmthicknesswasdecreasedbyonequarterofawavelengthoftheilluminatinglight19.0�mcompletedestructiveinterference44.Whatarethedifferencesinthecharacteris-ticsofthediffractionpatternsformedby80.0cmdiffractiongratingscontaining104lines/cmDoubleslitScreenand105lines/cm?■Figure19-17(Nottoscale)Thelinesinthediffractionpatternarexd����narrowerforthe105lines/cmgrating.L(19.0�10�6m)(1.90�10�2m)45.LaserPointerChallengeYouhavetwo�����80.0�10�2mlaserpointers,aredoneandagreenone.�451nmYourfriendsMarkandCarlosdisagreeaboutwhichhasthelongerwavelength.Mark48.OilSlickAfterashortspringshower,Tominsiststhatredlighthasalongerwavelength,andAnntaketheirdogforawalkandwhileCarlosissurethatgreenhasthelongernoticeathinfilmofoil(n�1.45)onawavelength.Youhaveadiffractiongratingpuddleofwater,producingdifferentcolors.handy.DescribewhatdemonstrationyouWhatistheminimumthicknessofaplacewoulddowiththisequipmentandhowyouwheretheoilcreatesconstructiveinterfer-wouldexplaintheresultstoCarlosandMarkenceforlightwithawavelengthof545nm?tosettletheirdisagreement.Thereisonephaseinversion,soShineeachlaserpointerthroughthegrat-constructiveinterferencewillbewheningontoanearbywall.Thecolorwiththe1�longerwavelengthwillproducedotswith2t��m�����2nfilmagreaterspacingonthewallbecausetheFortheminimumthickness,m�0.spacingisdirectlyproportionaltothewavelength.(Markiscorrect;redlighthast���1����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.4nalongerwavelengththangreenlight.)film545nm46.OpticalMicroscopeWhyisbluelightused���(4)(1.45)forilluminationinanopticalmicroscope?�94.0nmLessdiffractionresultsfromtheshortwavelengthofbluelight.Level249.Lightofwavelength542nmfallsonaMasteringProblemsdoubleslit.First-orderbrightbandsappear19.1Interference4.00cmfromthecentralbrightband.Thepages536—537screenis1.20mfromtheslits.Howfarapartaretheslits?Level147.Lightfallsonapairofslits19.0�mapartxd����and80.0cmfromascreen,asshowninLFigure19-17.Thefirst-orderbrightbandis�Ld���x1.90cmfromthecentralbrightband.Whatisthewavelengthofthelight?(5.42�10�7m)(1.20m)����4.00�10�2m�16.3�m50.InsulationFilmWinterisapproachingandAlejandroishelpingtocoverthewindows406SolutionsManualPhysics:PrinciplesandProblems
410Chapter19continuedinhishomewiththinsheetsofclearplasticfirst-orderbrightband,fromleasttomost(n�1.81)tokeepthedraftsout.Aftertheseparation.Specificallyindicateanyties.plasticistapeduparoundthewindowssuchxd����thatthereisairbetweentheplasticandtheLglasspanes,theplasticisheatedwithahair�Lx���dryertoshrink-wrapthewindow.Thethick-dnessoftheplasticisalteredduringthisBecause�isthesameforeachsetup,process.Alejandronoticesaplaceonthexcalculate��tocomparethesetups.plasticwherethereisabluestripeofcolor.�Herealizesthatthisiscreatedbythin-filmxL�����interference.Whatarethreepossiblethick-�dnessesoftheportionoftheplasticwhereSetupA:thebluestripeisproducedifthewavelength0.60mofthelightis4.40�102nm?���1.50�10�4mThereisonephaseinversion,so3�4.0�10constructiveinterferencewillbewhenSetupB:1�2t��m�����0.80m2nfilm����4m1.75�10Threepossiblethicknessesoccurat�4.6�103m�0,1,and2.SetupC:1�t������form�00.80m4nfilm���1.50�10�4m4.40�102nm���(4)(1.81)�5.3�103x�60.8nmC�xB�xA3�t������form�119.2Diffraction4nfilmpage537(3)(4.40�102nm)����Level1(4)(1.81)52.Monochromaticlightpassesthroughasin-�182nmgleslitwithawidthof0.010cmandfalls5�onascreen100cmaway,asshownint�����form�24nfilmFigure19-18.Ifthewidthofthecentral(5)(4.40�102nm)bandis1.20cm,whatisthewavelengthof����(4)(1.81)thelight?�304nmLevel351.Samirshinesaredlaserpointerthrough0.010cmthreedifferentdouble-slitsetups.InsetupA,theslitsareseparatedby0.150mmandthescreenis0.60mawayfromtheslits.In100cmSingleslitScreenCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.setupB,theslitsareseparatedby0.175mmandthescreenis0.80maway.SetupChas■Figure19-18(Nottoscale)theslitsseparatedby0.150mmandthe2�Lscreenadistanceof0.80maway.Rankthe2x1��w�threesetupsaccordingtotheseparationxwbetweenthecentralbrightbandandthe����LPhysics:PrinciplesandProblemsSolutionsManual407
411Chapter19continued(0.60cm)(0.010cm)x����obj1.22�100cm����LDobj�600nm1.22�Lobjx��3linesobj�D53.Agooddiffractiongratinghas2.5�10percm.Whatisthedistancebetweentwo(1.22)(5.1�10�7m)(1.0�105m)�����linesinthegrating?2.4m1�2.6�10�2md����2.5�103lines/cm�2.6cm�4.0�10�4cmLevel3Level256.Monochromaticlightwithawavelengthof54.Lightwithawavelengthof4.5�10�5cm425nmpassesthroughasingleslitandpassesthroughasingleslitandfallsonafallsonascreen75cmaway.Ifthecentralscreen100cmaway.Iftheslitis0.015cmbrightbandis0.60cmwide,whatisthewide,whatisthedistancefromthecenterwidthoftheslit?ofthepatterntothefirstdarkband?2�L2x��1�w2�L2x��1�w2�L�Lw�����2xx2x1isthewidthofthebrightband,so11togetthedistancefromthecenterto1thefirstdarkband,divideby2.x1���2��(2x1)�0.30cm�L(4.25�10�5cm)(75cm)x1��w�����0.30cm(4.5�10�5cm)(100m)�1.1�10�2cm����0.015cm�0.3cm57.KaleidoscopeJenniferisplayingwithakaleidoscopefromwhichthemirrorshaveCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.55.HubbleSpaceTelescopeSupposetheHubblebeenremoved.TheeyeholeattheendisSpaceTelescope,2.4mindiameter,isinorbit7.0mmindiameter.Ifshecanjustdistin-1.0�105maboveEarthandisturnedtoguishtwobluish-purplespecksontheotherviewEarth,asshowninFigure19-19.Ifendofthekaleidoscopeseparatedby40�m,youignoretheeffectoftheatmosphere,whatisthelengthofthekaleidoscope?howlargeanobjectcanthetelescopeUse��650nmandassumethattheresolve?Use��5.1�10�7m.resolutionisdiffractionlimitedthroughtheeyehole.1.22�Lobjx��obj�DxobjDL�obj�1.22�(40�10�6m)(7.0�10�3m)�����(1.22)(650�10�9m)�0.4m■Figure19-19408SolutionsManualPhysics:PrinciplesandProblems
412Chapter19continued58.SpectroscopeAspectroscopeusesagrat-632.8�10�9m���ingwith12,000lines/cm.Findtheanglesat�121�103msin�tan�����whichredlight,632nm,andbluelight,4.0m421nm,havefirst-orderbrightlines.�1.2�10�4m�1.2�10�2cmd����18.33�10�5cm1112,000lines/cm�d����1.2�10�2cm83ridges/cm��dsin�b.Mariechecksherresultsbynotingthat�theridgesrepresentasongthatlastssin����d4.01minutesandtakesup16mmonForredlight,therecord.Howmanyridgesshould�16.32�10�5cmtherebeinacentimeter?��sin����8.33�10�5cmNumberofridgesis�49.3°(4.01min)(33.3rev/min)�134ridgesForbluelight,134ridges���84ridges/cm�14.21�10�5cm1.6cm��sin����8.33�10�5cmLevel2�30.3°60.Ananti-reflectivecoating,n�1.2,isappliedtoalens.IfthethicknessoftheMixedReviewcoatingis125nm,whatis(are)thepage538color(s)oflightforwhichcompleteLevel1destructiveinterferencewilloccur?Hint:159.RecordMarieusesanold33��rpmrecordAssumethelensismadeoutofglass.3asadiffractiongrating.Sheshinesalaser,Becausenfilm�nair,thereisaphase��632.8nm,ontherecord,asshownininversiononthefirstreflection.Figure19-20.Onascreen4.0mfromtheBecausenrecord,aseriesofreddots21mmapartarelens�1.52�nfilm,thereisaphaseinversiononthesecondreflection.visible.Fordestructiveinterference:Laser1�2d��m�����2nfilm21mm2dnfilm���1�m����2(2)(125nm)(1.2)21mmRecord���1�m��2��Screen1�12nm)4.0m��m���(3.0�102■Figure19-20(Nottoscale)Form�0a.Howmanyridgesarethereinacen-1�12nm)�����(3.0�10timeteralongtheradiusoftherecord?2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��dsin��6.0�102nm��Thelightisreddish-orange.Forotherd������sin�sintan�1xvaluesofm,thewavelengthisshorter������Lthanthatoflight.Physics:PrinciplesandProblemsSolutionsManual409
413Chapter19continuedLevel363.ApplyConceptsBluelightofwavelength�61.CameraWhenacamerawitha50-mmpassesthroughasingleslitofwidthw.Alensissetatf/8,itsaperturehasanopeningdiffractionpatternappearsonascreen.If6.25mmindiameter.younowreplacethebluelightwithagreena.Forlightwith��550nm,whatislightofwavelength1.5�,towhatwidththeresolutionofthelens?Thefilmisshouldyouchangetheslittogettheoriginal50.0mmfromthelens.patternback?1.22�LobjTheangleofdiffractiondependsonthex��obj�Dratioofslitwidthtowavelength.Thus,(1.22)(5.5�10�4mm)(50.0mm)youwouldincreasethewidthto1.5w.�����6.25mm64.AnalyzeandConcludeAtnight,thepupil�5.4�10�3mmofahumaneyehasanaperturediameterb.Theownerofacameraneedstodecideof8.0mm.Thediameterissmallerinwhichfilmtobuyforit.Theexpensivedaylight.Anautomobile’sheadlightsareone,calledfine-grainedfilm,hasseparatedby1.8m.200grains/mm.Thelesscostly,coarse-a.BaseduponRayleigh’scriterion,howfargrainedfilmhasonly50grains/mm.Ifawaycanthehumaneyedistinguishthetheownerwantsagraintobenosmallertwoheadlightsatnight?Hint:Assumeathanthewidthofthecentralbrightspotwavelengthof525nm.calculatedinparta,whichfilmshould1.22�Lhepurchase?objx��obj�DCentralbrightbandwidthx�3mmL�ob�jD2x��10.7�10obj�1.22�1(8.0�10�3m)(1.80m)The200grains/mmfilmhas��200mm�����7m)(1.22)(5.25�10betweengrains�5�10�3mm,so�2.2�104m�22kmthisfilmwillwork.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1b.Canyouactuallyseeacar’sheadlightsThe50grains/mmhas��50mmatthedistancecalculatedinparta?betweengrains�20�10�3mm,soDoesdiffractionlimityoureyes’sensingthisfilmwon’twork.ability?Hypothesizeastowhatmightbethelimitingfactors.ThinkingCriticallyNo;afewhundredmeters,notsever-page538alkilometers,isthelimit.Diffraction62.ApplyConceptsYellowlightfallsonadif-doesn’tlimitthesensingabilityoffractiongrating.Onascreenbehindtheyoureyes.Moreprobablefactorsaregrating,youseethreespots:oneatzerotherefractiveeffectsoftheatmos-degrees,wherethereisnodiffraction,andphere,likethosethatcausestarstooneeachat�30°and�30°.Younowaddtwinkle,orthelimitationsofthereti-abluelightofequalintensitythatisinthenaandtheopticareaofthebraintosamedirectionastheyellowlight.Whatseparatetwodimsources.patternofspotswillyounowseeonthescreen?WritinginPhysicsAgreenspotat0°,yellowspotsat�30°page538and�30°,andtwobluespotsslightly65.ResearchanddescribeThomasYoung’scon-closerin.tributionstophysics.Evaluatetheimpactofhisresearchonthescientificthoughtaboutthenatureoflight.410SolutionsManualPhysics:PrinciplesandProblems
414Chapter19continuedStudentanswerswillvary.Answersa.WhatisthewavelengthofthesoundinshouldincludeYoung’stwo-slitexperi-stillair?mentthatallowedhimtoprecisely1.50mmeasurethewavelengthoflight.b.Ifthespeedofsoundis330m/s,whatisthefrequencyofthesource?66.Researchandinterprettheroleofdiffrac-tioninmedicineandastronomy.Describev�f�atleasttwoapplicationsineachfield.v330m/sf�������220HzStudentanswerswillvary.Answers�1.50mcouldincludediffractionintelescopesc.Whatisthespeedoftheairplane?andmicroscopes,aswellasTheplanemovesforward0.50mspectroscopy.forevery1.50mthatthesoundwavetravels,sotheplane’sspeedisone-CumulativeReviewthirdthespeedofsound,or110m/s.page53867.Howmuchworkmustbedonetopusha70.Aconcavemirrorhasa48.0-cmradius.A0.5-m3blockofwoodtothebottomofa2.0-cm-tallobjectisplaced12.0cmfrom4-m-deepswimmingpool?Thedensityofthemirror.Calculatetheimagepositionwoodis500kg/m3.(Chapter13)andimageheight.(Chapter17)Theblockwouldfloat,buttosubmergeitrf���wouldrequireanextraforcedownward.2W�Fd��48.0�cm2F�Fbuoyancy�Fg�24.0cmFg��Vg111���������(500kg/m3)(0.5m3)(9.80m/s2)fdodid�2450Nd�ofi�dFo�fbuoyancy��Vg�(1000kg/m3)(0.5m3)(12.0cm)(24.0cm)����12.0cm�24.0cm(9.80m/s2)��24.0cm�4900Nh�dWork�(4900N�2450N)(4m)m���i���ihdoo�10kJ�dhh��ioi�d68.Whatarethewavelengthsofmicrowavesinoanoveniftheirfrequencyis2.4GHz?�(�24.0cm)(2.0cm)����(Chapter14)12.0cmc�f��4.0cmc3.00�108m/s�������9Hzf2.4�1071.Thefocallengthofaconvexlensis21.0cm.�0.12mA2.00-cm-tallcandleislocated7.50cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.fromthelens.Usethethin-lensequation69.Soundwavecreststhatareemittedbyantocalculatetheimagepositionandimageairplaneare1.00mapartinfrontoftheheight.(Chapter18)plane,and2.00mapartbehindtheplane.111��������(Chapter15)fddoiPhysics:PrinciplesandProblemsSolutionsManual411
415Chapter19continueddxd�ofUse(1)���minw,(2)vi�dLsubstance��f,o�f(7.50cm)(21.0cm)cand(3)n�����substance�v.7.50cm�21.0cmCombine(2)and(3).��11.7cm�f�n��vacuum��vacuumhi�disubstance���f�(4),m�����substancesubstancehdoobecausethefrequencyremainsconstant�dh�ihoasthelightcrossesaboundary.i�doRewrite(1)intermsofasubstancein�(�11.7cm)(2.00cm)thespacebetweentheslitsandthe����7.50cmscreen.�3.11cmxminw��substance�L(5)Combine(4)and(5)andsolveforx.ChallengeProblem�vacuumnsubstance��xwpage526�min�LYouhaveseveralunknownsubstancesandwish�touseasingle-slitdiffractionapparatustodeter-x��vacuumLmin�nminewhateachoneis.Youdecidetoplaceasubstancewsampleofanunknownsubstanceintheregion2.Ifthesourceyouusedhadawavelengthofbetweentheslitandthescreenandusethedata634nm,theslitwidthwas0.10mm,thethatyouobtaintodeterminetheidentityofeachdistancefromtheslittothescreenwassubstancebycalculatingitsindexofrefraction.1.15m,andyouimmersedtheapparatusinwater(nsubstance�1.33),thenwhatwouldyouexpectthewidthofthecenterUnknownbandtobe?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.substance�x���vacuumLnsubstancedx1(634�10�9m)(1.15m)����(1.33)(0.10�10�3m)�5.5�10–3mLIncominglight1.Comeupwithageneralformulafortheindexofrefractionofanunknownsub-stanceintermsofthewavelengthofthelight,�vacuum,thewidthoftheslit,w,thedistancefromtheslittothescreen,L,andthedistancebetweenthecentralbrightbandandthefirstdarkband,x1.412SolutionsManualPhysics:PrinciplesandProblems
416CHAPTER20StaticElectricityThewoolbecomespositivelychargedSectionReviewbecauseitgivesupelectronstothe20.1ElectricChargerubberrod.pages541–5455.ConservationofChargeAnapplecon-page545tainstrillionsofchargedparticles.Why1.ChargedObjectsAfteracombisrubbeddon’ttwoapplesrepeleachotherwhenonawoolsweater,itisabletopickuptheyarebroughttogether?smallpiecesofpaper.WhydoesthecombEachapplecontainsequalnumbersoflosethatabilityafterafewminutes?positiveandnegativecharges,sotheyThecomblosesitschargetoitssur-appearneutraltoeachother.roundingsandbecomesneutralonceagain.6.ChargingaConductorSupposeyouhangalongmetalrodfromsilkthreadssothat2.TypesofChargeIntheexperimentstherodisisolated.Youthentouchadescribedearlierinthissection,howcouldchargedglassrodtooneendofthemetalyoufindoutwhichstripoftape,BorT,isrod.Describethechargesonthemetalrod.positivelycharged?TheglassrodattractselectronsoffBringapositivelychargedglassrodthemetalrod,sothemetalbecomesnearthetwostripsoftape.Theonethatpositivelycharged.Thechargeisdis-isrepelledbytherodispositive.tributeduniformlyalongtherod.3.TypesofChargeApithballisasmall7.ChargingbyFrictionYoucanchargeaspheremadeofalightmaterial,suchasplas-rubberrodnegativelybyrubbingitwithticfoam,oftencoatedwithalayerofgraphitewool.Whathappenswhenyourubacop-oraluminumpaint.Howcouldyoudeter-perrodwithwool?minewhetherapithballthatissuspendedBecausethecopperisaconductor,itfromaninsulatingthreadisneutral,isremainsneutralaslongasitisincon-chargedpositively,orischargednegatively?tactwithyourhand.Bringanobjectofknowncharge,suchasanegativelychargedhardrubber8.CriticalThinkingItoncewasproposedrod,nearthepithball.Ifthepithballisthatelectricchargeisatypeoffluidthatrepelled,ithasthesamechargeastheflowsfromobjectswithanexcessoftherod.Ifitisattracted,itmayhavethefluidtoobjectswithadeficit.Whyistheoppositechargeorbeneutral.Tofindcurrenttwo-chargemodelbetterthantheoutwhich,bringapositivelychargedsingle-fluidmodel?glassrodnearthepithball.IftheyThetwo-chargemodelcanbetterrepel,thepithballispositive;iftheyexplainthephenomenaofattractionattract,thepithballmustbeneutral.andrepulsion.ItalsoexplainshowCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.objectscanbecomechargedwhenthey4.ChargeSeparationArubberrodcanbearerubbedtogether.Thesingle-fluidchargednegativelywhenitisrubbedwithmodelindicatedthatthechargeshouldwool.Whathappenstothechargeofthebeequalizedonobjectsthatareincon-wool?Why?tactwitheachother.Physics:PrinciplesandProblemsSolutionsManual413
417Chapter20continuedPracticeProblems20.2ElectricForcepages546–553page5529.Anegativechargeof�2.0�10�4Candapositivechargeof8.0�10�4Careseparatedby0.30m.Whatistheforcebetweenthetwocharges?KqAqB(9.0�109N�m2/C2)(2.0�10�4C)(8.0�10�4C)F���������d2(0.30m)2AB�1.6�104N10.Anegativechargeof�6.0�10�6Cexertsanattractiveforceof65Nonasecondchargethatis0.050maway.Whatisthemagnitudeofthesecondcharge?KqAqBF��d2ABFd22AB(65N)(0.050m)q�����B��Kq(9.0�109N�m2/C2)(6.0�10�6C)A�3.0�10�6C11.ThechargeonBinExampleProblem1isreplacedbyachargeof�3.00�C.DiagramthenewsituationandfindthenetforceonA.Magnitudesofallforcesremainthesame.Thedirectionchangesto42°abovethe�xaxis,or138°.12.SphereAislocatedattheoriginandhasachargeof�2.0�10�6C.SphereBislocatedat�0.60monthex-axisandhasachargeof�3.6�10�6C.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.SphereCislocatedat�0.80monthex-axisandhasachargeof�4.0�10�6C.DeterminethenetforceonsphereA.qAqB9N�m2/C2)(2.0�10�6C)(3.6�10�6C)�0.18NF�����BonA�Kd2�(9.0�10(0.60m)2ABdirection:towardtherightqAqC9N�m2/C2)(2.0�10�6C)(4.0�10�6C)�0.1125�NF�����ConA�Kd2�(9.0�10(0.80m)2ACdirection:towardtheleftFnet�FBonA�FConA�(0.18N)�(0.1125N)�0.068Ntowardtheright13.DeterminethenetforceonsphereBinthepreviousproblem.qAqBF�AonB�Kd2ABqAqBF�ConB�Kd2ABFnet�FConB�FAonBqqBqCAqB�K��K�d2d2BCAB414SolutionsManualPhysics:PrinciplesandProblems
418Chapter20continued�(9.0�109N�m2/C2)b.anegativerod.(3.6�10�6C)(4.0�10�6C)Bringthenegativerodnear,butnot�����(0.20m)2touchingtheelectroscope.Touch(9.0�109N�m2/C2)(ground)theelectroscopewithyourfinger,allowingelectronstobe(2.0�10�6C)(3.6�10�6C)repelledoffoftheelectroscopeinto����(0.60m)2yourfinger.Removeyourfingerand�3.1Ntowardtherightthenremovetherod.18.AttractionofNeutralObjectsWhattwoSectionReviewpropertiesexplainwhyaneutralobjectisattractedtobothpositivelyandnegatively20.2ElectricForcechargedobjects?pages546–553Chargeseparation,causedbythepage553attractionofoppositechargesandthe14.ForceandChargeHowareelectricforcerepulsionoflikecharges,movestheandchargerelated?Describetheforcewhenoppositechargesintheneutralbodythechargesarelikechargesandtheforceclosertothechargedobjectandthewhenthechargesareoppositecharges.likechargesfartheraway.TheinverserelationbetweenforceanddistanceElectricforceisdirectlyrelatedtoeachmeansthatthenearer,oppositecharge.Itisrepulsivebetweenlikechargeswillattractmorethanthemorechargesandattractivebetweenoppo-distant,likechargeswillrepel.Thesitecharges.overalleffectisattraction.15.ForceandDistanceHowareelectricforce19.ChargingbyInductionInanelectroscopeanddistancerelated?Howwouldtheforcebeingchargedbyinduction,whathappenschangeifthedistancebetweentwochargeswhenthechargingrodismovedawaybeforeweretripled?thegroundisremovedfromtheknob?ElectricforceisinverselyrelatedtoChargethathadbeenpushedintothethesquareofthedistancebetweengroundbytherodwouldreturntothecharges.Ifthedistanceistripled,theelectroscopefromtheground,leavingforcewillbeone-ninthasgreat.theelectroscopeneutral.16.ElectroscopesWhenanelectroscopeis20.ElectricForcesTwochargedspheresareheldcharged,theleavesrisetoacertainangleadistance,r,apart.Onespherehasachargeofandremainatthatangle.Whydotheynot�3�C,andtheotherspherehasachargeofrisefarther?�9�C.Comparetheforceofthe�3�CAstheleavesmovefartherapart,thesphereonthe�9�Cspherewiththeforceofelectricforcebetweenthemdecreasesthe�9�Csphereonthe�3�Csphere.untilitisbalancedbythegravitationalTheforcesareequalinmagnitudeandforcepullingdownontheleaves.oppositeindirection.17.CharginganElectroscopeExplainhowto21.CriticalThinkingSupposethatyouareCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.chargeanelectroscopepositivelyusingtestingCoulomb’slawusingasmall,posi-a.apositiverod.tivelychargedplasticsphereandalarge,Touchthepositiverodtotheelectro-positivelychargedmetalsphere.Accordingscope.NegativechargeswillmovetoCoulomb’slaw,theforcedependsontotherod,leavingtheelectroscope1/r2,whereristhedistancebetweenthepositivelycharged.centersofthespheres.AsthespheresgetPhysics:PrinciplesandProblemsSolutionsManual415
419Chapter20continuedclosetogether,theforceissmallerthan26.LaundryWhydosockstakenfromaclothesexpectedfromCoulomb’slaw.Explain.dryersometimesclingtootherclothes?(20.2)SomechargesonthemetalspherewillTheyhavebeenchargedbycontactasberepelledtotheoppositesidefromtheyrubagainstotherclothes,andtheplasticsphere,makingtheeffectivethus,areattractedtoclothingthatisdistancebetweenthechargesgreaterneutralorhasanoppositecharge.thanthedistancebetweenthespheres’centers.27.CompactDiscsIfyouwipeacompactdiscwithacleancloth,whydoestheCDthenattractdust?(20.2)ChapterAssessmentRubbingtheCDchargesit.Neutralparticles,suchasdust,areattractedtoConceptMappingachargedobject.page55822.Completetheconceptmapbelowusingthe28.CoinsThecombinedchargeofallelectronsfollowingterms:conduction,distance,elemen-inanickelishundredsofthousandsoftarycharge.coulombs.Doesthisimplyanythingaboutthenetchargeonthecoin?Explain.(20.2)ElectricForceNo.Netchargeisthedifferencebetweenpositiveandnegativecharges.ThecoinCoulomb’schargingstillcanhaveanetchargeofzero.law29.Howdoesthedistancebetweentwochargedistancechargesimpacttheforcebetweenthem?Ifthedistanceisdecreasedwhilethechargesremainthesame,whathappenselementarycoulombconductioninductionchargetotheforce?(20.2)ElectricforceisinverselyproportionalCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.MasteringConceptstothedistancesquared.Asdistancedecreasesandchargesremainthepage558same,theforceincreasesasthesquare23.Ifyoucombyourhaironadryday,theofthedistance.combcanbecomepositivelycharged.Canyourhairremainneutral?Explain.(20.1)30.Explainhowtochargeaconductornega-No.Byconservationofcharge,yourtivelyifyouhaveonlyapositivelychargedhairmustbecomenegativelycharged.rod.(20.2)Bringtheconductorcloseto,butnot24.Listsomeinsulatorsandconductors.(20.1)touching,therod.GroundtheconductorStudentanswerswillvarybutmayinthepresenceofthechargedrod;then,includedryair,wood,plastic,glass,removethegroundbeforeremovingthecloth,anddeionizedwaterasinsula-chargedrod.Theconductorwillhaveators;andmetals,tapwater,andyournetnegativecharge.bodyasconductors.ApplyingConcepts25.Whatpropertymakesmetalagoodconduc-page558torandrubberagoodinsulator?(20.1)31.HowdoesthechargeofanelectrondifferMetalscontainfreeelectrons;rubberfromthechargeofaproton?Howaretheyhasboundelectrons.similar?416SolutionsManualPhysics:PrinciplesandProblems
420Chapter20continuedThechargeoftheprotonisexactlytheLawofsamesizeastheelectron,buthastheUniversalGravitationCoulomb’sLawoppositesign.F�G�mA�mBqAqBr2F�K��232.Usingachargedrodandanelectroscope,rhowcanyoufindwhetherornotanobjectmAmBqAqBisaconductor?��Useaknowninsulatortoholdoneendoftheobjectagainsttheelectroscope.rrTouchtheotherendwiththechargedrod.Iftheelectroscopeindicatesa■Figure20-13(Nottoscale)charge,theobjectisaconductor.Similar:inverse-squaredependenceondistance,forceproportionaltoproduct33.Achargedrodisbroughtnearapileoftinyoftwomassesortwocharges;differ-plasticspheres.Someofthespheresareent:onlyonesignofmass,sogravita-attractedtotherod,butassoonastheytionalforceisalwaysattractive;twotouchtherod,theyareflungoffindifferentsignsofcharge,soelectricforcecandirections.Explain.beeitherattractiveorrepulsive.Thenaturalspheresareinitiallyattract-edtothechargedrod,buttheyacquire37.Theconstant,K,inCoulomb’sequationisthesamechargeastherodwhentheymuchlargerthantheconstant,G,inthetouchit.Asaresult,theyarerepelleduniversalgravitationequation.Ofwhatsig-fromtherod.nificanceisthis?Theelectricforceismuchlargerthan34.LightningLightningusuallyoccurswhenathegravitationalforce.negativechargeinacloudistransportedtoEarth.IfEarthisneutral,whatprovidesthe38.ThetextdescribesCoulomb’smethodforattractiveforcethatpullstheelectronschargingtwospheres,AandB,sothatthetowardEarth?chargeonBwasexactlyhalfthechargeonThechargeinthecloudrepelselec-A.SuggestawaythatCoulombcouldhavetronsonEarth,causingachargesepa-placedachargeonsphereBthatwasexactlyrationbyinduction.ThesideofEarthone-thirdthechargeonsphereA.closesttothecloudispositive,result-AfterchangingspheresAandBequally,inginanattractiveforce.sphereBistouchedtotwootherequallysizedballsthataretouching35.Explainwhathappenstotheleavesofaeachother.ThechargeonBwillbepositivelychargedelectroscopewhenrodsdividedequallyamongallthreeballs,withthefollowingchargesarebroughtleavingone-thirdthetotalchargeonit.closeto,butnottouching,theelectroscope.a.positive39.CoulombmeasuredthedeflectionofsphereAwhenspheresAandBhadequalchargesTheleaveswillmovefartherapart.andwereadistance,r,apart.Hethenmadeb.negativethechargeonBone-thirdthechargeonA.Theleaveswilldropslightly.HowfarapartwouldthetwospheresthenCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.havehadtobeforAtohavehadthesame36.AsshowninFigure20-13,Coulomb’slawdeflectionthatithadbefore?andNewton’slawofuniversalgravitationTohavethesameforcewithone-thirdappeartobesimilar.Inwhatwaysarethethecharge,thedistancewouldhaveelectricandgravitationalforcessimilar?tobedecreasedsuchthatd2�1/3,orHowaretheydifferent?0.58timesasfarapart.Physics:PrinciplesandProblemsSolutionsManual417
421Chapter20continued40.Twochargedbodiesexertaforceof0.145Noneachother.Iftheyaremovedsothattheyareone-fourthasfarapart,whatforceisexerted?11F���2andF��,soF�16timestheoriginalforce.d12����441.Electricforcesbetweenchargesareenormousincomparisontogravitationalforces.Yet,wenormallydonotsenseelectricforcesbetweenusandoursurroundings,whilewedosensegravitationalinteractionswithEarth.Explain.Gravitationalforcesonlycanbeattractive.Electricforcescanbeeitherattractiveorrepulsive,andwecansenseonlytheirvectorsums,whicharegenerallysmall.ThegravitationalattractiontoEarthislargerandmorenoticeablebecauseofEarth’slargemass.MasteringProblems20.2ElectricForcepage559Level142.Twocharges,qAandqB,areseparatedbyadistance,r,andexertaforce,F,oneachother.AnalyzeCoulomb’slawandidentifywhatnewforcewouldexistunderthefollowingconditions.a.qAisdoubled2qA,thennewforce�2Fb.qAandqBarecutinhalf11111�2qAand�2qB,thennewforce���2����2��F��4Fc.ristripledCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.F13d,thennewforce����F(3)29d.riscutinhalf1F3�d,thennewforce����F�4F2124����2e.qAistripledandrisdoubled(3)F33q��Aand2d,thennewforce��(2)24F43.LightningAstronglightningbolttransfersabout25CtoEarth.Howmanyelectronsaretransferred?1electron20electrons(�25C)�����1.6�10�1.60�10�19C44.AtomsTwoelectronsinanatomareseparatedby1.5�10�10m,thetypicalsizeofanatom.Whatistheelectricforcebetweenthem?KqAqB(9.0�109N�m2/C2)(1.60�10�19C)(1.60�10�19C)F����������d2(1.5�10�10m)2�1.0�10�8N,awayfromeachother418SolutionsManualPhysics:PrinciplesandProblems
422Chapter20continued45.Apositiveandanegativecharge,eachofmagnitude2.5�10�5C,areseparatedbyadistanceof15cm.Findtheforceoneachoftheparticles.KqAqB(9.0�109N�m2/C2)(2.5�10�5C)(2.5�10�5C)F���2������(1.5�10�1m)2d�2.5�102N,towardtheothercharge46.Aforceof2.4�102Nexistsbetweenapositivechargeof8.0�10�5Candapositivechargeof3.0�10�5C.Whatdistanceseparatesthecharges?KqAqBF��d2KqAqB(9.0�109N�m2/C2)(8.0�10�5C)(3.0�10�5C)d�����������F����2.4�102N�0.30m47.Twoidenticalpositivechargesexertarepulsiveforceof6.4�10�9Nwhenseparatedbyadistanceof3.8�10�10m.Calculatethechargeofeach.KqAqBKq2F������d2d2Fd2(6.4�10�9N)(3.8�10�10m)2q������������9N�m2/C2�3.2�10�19CK9.0�10Level248.Apositivechargeof3.0�Cispulledonbytwo�4.0�Cnegativecharges.AsshowninFigure20-14,one�2.0�C�3.0�Cnegativecharge,�2.0�C,is0.050mtothewest,andtheother,�4.0�C,is0.030mtotheeast.���Whattotalforceisexertedonthepositivecharge?0.050m0.030m(9.0�109N�m2/C2)(3.0�10�6C)(2.0�10�6C)F1�������(0.050m)2■Figure20-14�22Nwest(9.0�109N�m2/C2)(3.0�10�6C)(4.0�10�6C)F������2�(0.030m)2�120NeastF2N)�(2.2�101N)net�F2�F1�(1.2�10�98N,east49.Figure20-15showstwopositivelychargedq3qspheres,onewiththreetimesthechargeofthe��other.Thespheresare16cmapart,andtheforceCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.betweenthemis0.28N.Whatarethecharges16cmonthetwospheres?■Figure20-15qAqBqA3qAF�K���K�d2d2Physics:PrinciplesandProblemsSolutionsManual419
423Chapter20continuedFd2(0.28N)(0.16m)2q�����7CA���3K����3(9.0�109N�m2/C2)�5.2�10q�6CB�3qA�1.5�1050.ChargeinaCoinHowmanycoulombsofchargeareontheelectronsinanickel?Usethefollowingmethodtofindtheanswer.a.Findthenumberofatomsinanickel.Anickelhasamassofabout5g.Anickelis75percentCuand25percentNi,soeachmoleofthecoin’satomswillhaveamassofabout62g.5gAcoinis��0.08mole.62gThus,ithas(0.08)(6.02�1023)�5�1022atomsb.Findthenumberofelectronsinthecoin.Onaverage,eachatomhas28.75electrons.(5�1022atoms)(28.75electrons/atom)�1�1024electronsc.Findthecoulombsontheelectrons.(1.6�10�19coulombs/electron)(1�1024electrons)�2�105coulombs51.Threeparticlesareplacedinaline.Theleftparticlehasachargeof�55�C,themiddleonehasachargeof�45�C,andtherightonehasachargeof�78�C.Themiddleparticleis72cmfromeachoftheothers,asshowninFigure20-16.�55�C�45�C�78�C���72cm72cm■Figure20-16Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Findthenetforceonthemiddleparticle.LetleftbethenegativedirectionKqmqlKqmqrF����net��Fl�(Fr)��d2d2�(9.0�109N�m2/C2)(45�10�6C)(55�10�6C)��������(0.72m)2(9.0�109N�m2/C2)(45�10�6C)(78�10�6C)������(0.72m)2�18N,rightb.Findthenetforceontherightparticle.KqKqlqrmqrF����net�Fl�(�Fm)��(2d)2d2(9.0�109N�m2/C2)(55�10�6C)(78�10�6C)��������(2(0.72m))2(9.0�109N�m2/C2)(45�10�6C)(78�10�6C)������(0.72m)2��42N,left420SolutionsManualPhysics:PrinciplesandProblems
424Chapter20continuedMixedReviewpage559Level152.Asmallmetalspherewithcharge1.2�10�5Cistouchedtoanidenticalneutralsphereandthenplaced0.15mfromthesecondsphere.Whatistheelectricforcebetweenthetwospheres?Thetwospheressharethechargeequally,soqAqB9N�m2�C2)(6.0�10�6C)(6.0�10�6C)�14NF�K��(9.0�10����d2(0.15m)253.AtomsWhatistheelectricforcebetweenanelectronandaprotonplaced5.3�10�11mapart,theapproximateradiusofahydrogenatom?qAqB9N�m2�C2)(1.60�10�19C)(1.60�10�19C)�8.2�10�8NF�K��(9.0�10����d2(5.3�10�11m)254.Asmallsphereofcharge2.4�Cexperiencesaforceof0.36Nwhenasecondsphereofunknownchargeisplaced5.5cmfromit.Whatisthechargeofthesecondsphere?qAqBF�K�d2Fd2(0.36N)(5.5�10�2m)2q������8CB��Kq(9.0�109N�m2�C2)(2.4�10�6C)�5.0�10A55.Twoidenticallychargedspheresplaced12cmaparthaveanelectricforceof0.28Nbetweenthem.Whatisthechargeofeachsphere?qAqBF�K�,whereqd2A�qBFd2(0.28N)(1.2�10�1m)2q��������K���(9.0�109N�m2�C2)�6.7�10�7C56.InanexperimentusingCoulomb’sapparatus,aspherewithachargeof3.6�10�8Cis1.4cmfromasecondsphereofunknowncharge.Theforcebetweenthespheresis2.7�10�2N.Whatisthechargeofthesecondsphere?qAqBF�K�d2Fd2(2.7�10�2N)(1.4�10�2m)2q������B��Kq����(9.0�109N�m2�C2)(3.6�10�8C)A�1.6�10�8C57.Theforcebetweenaprotonandanelectronis3.5�10�10N.Whatisthedistancebetweenthesetwoparticles?qAqBF�K�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.d2qAqBd�K����F2�19C)(1.6�10�19C)�(9.0�109N�m2/C2)(1.60�����10�8.1�10�10m�������3.5�10�10NPhysics:PrinciplesandProblemsSolutionsManual421
425Chapter20continuedThinkingCriticallypage56058.ApplyConceptsCalculatetheratiooftheelectricforcetothegravitationalforcebetweentheelectronandtheprotoninahydrogenatom.qqepK��2dFe�mmKqeqp����G�e�p��Fgd2Gmemp(9.0�109N�m2/C2)(1.60�10�19C)239���������2.3�10(6.67�10�11N�m2/kg2)(9.11�10�31kg)(1.67�10�27kg)59.AnalyzeandConcludeSphereA,withachargeof�64�C,ispositionedattheorigin.Asecondsphere,B,withachargeof�16�C,isplacedat11.00monthex-axis.a.Wheremustathirdsphere,C,ofcharge�12�Cbeplacedsothereisnonetforceonit?Theattractiveandrepulsiveforcesmustcancel,soqqAqCBqCF��AC�Kd2�Kd2�FBC,soACBCqq��A���B,and16d2�64d2,ord2d2ACBCACBCd2�4d2,sodACBCAC�2dBCThethirdspheremustbeplacedat�2.00monthex-axissoitistwiceasfarfromthefirstsphereasfromthesecondsphere.b.Ifthethirdspherehadachargeof�6�C,whereshoulditbeplaced?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thethirdcharge,qc,cancelsfromtheequation,soitdoesn’tmatterwhatitsmagnitudeorsignis.c.Ifthethirdspherehadachargeof�12�C,whereshoulditbeplaced?Asinpartb,themagnitudeandsignofthethirdcharge,qc,donotmatter.60.ThreechargedspheresarelocatedatthepositionsshowninFigure20-17.FindthetotalforceonsphereB.�y�4.5�C�8.2�CA���x4.0cmB3.0cm��6.0�CC■Figure20-17F1�FAonBKqAqB(9.0�109N�m2/C2)(4.5�10�6C)(�8.2�10�6C)���������d2(0.040m)2422SolutionsManualPhysics:PrinciplesandProblems
426Chapter20continued��208N�208N,toleftThedistancebetweentheothertwochargesis�(0.040��m)2��(0.030m)�2�0.050m�10.030m�1�tan��0.04�0m��37°belowthenegativex-axis,or217°fromthepositivex-axis.F2�FConBKqCqB(9.0�109N�m2/C)(8.2�10�6C)(6.0�10�6C)���������d2(0.050m)2��177N�177Nat217°fromthepositivex-axis(37°�180°)ThecomponentsofF2are:F2x�F2cos��(177N)(cos217°)��142N�142NtotheleftF2y�F2sin��(177N)(sin217°)��106N�106NdownThecomponentsofthenet(resultant)forceare:Fnet,x��208N�142N��350N�350N,toleftFnet,y�106N,downFnet��(350N��)2�(1�06N)2�366N�3.7�102N�1106N�2�tan���350N�17°belowthenegativex-axisF2Nat197°fromthepositivex-axisnet�3.7�1061.ThetwopithballsinFigure20-18eachhaveamassof1.0gandanequalcharge.Onepithballissuspendedbyaninsulatingthread.Theotherisbroughtto3.0cmfromthesuspendedball.Thesuspendedballisnowhangingwiththethreadforminganangleof30.0°withthevertical.TheballisinequilibriumwithFE,Fg,andFT.Calculateeachofthefollowing.30.0°FE3.0cm■Figure20-18a.FgonthesuspendedballCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.F�3kg)(9.80m/s2)�9.8�10�3Ng�mg�(1.0�10b.FEFEtan30.0°���FgPhysics:PrinciplesandProblemsSolutionsManual423
427Chapter20continuedFE�mgtan30.0°�(1.0�10�3kg)(9.80m/s2)(tan30.0°)�5.7�10�3Nc.thechargeontheballsKqqABF���d2Kq2F��d2Fd2(5.7�10�3N)(3.0�10�2m2)�8Cq��������2.4�10��K���(9.0�109N�m2/C2)62.Twocharges,qAandqB,areatrestnearapositivetestcharge,qT,of7.2�C.Thefirstcharge,qA,isapositivechargeof3.6�Clocated2.5cmawayfromqTat35°;qBisanegativechargeof�6.6�Clocated6.8cmawayat125°.a.DeterminethemagnitudeofeachoftheforcesactingonqT.KqTqA(9.0�109N�m2/C2)(7.2�10�6C)(3.6�10�6C)F���������A�d2(0.025m)2�3.7�102N,away(towardqT)KqTqA(9.0�109N�m2/C2)(7.2�10�6C)(6.6�10�6C)F���������B�d2(0.068m)2�92N,toward(awayfromqT)b.Sketchaforcediagram.qA�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3.7�102NqBFA�125°FB35°92N�qTc.GraphicallydeterminetheresultantforceactingonqT.21°35°F�3.8�102NFA�3.7�102NFB�92N424SolutionsManualPhysics:PrinciplesandProblems
428Chapter20continuedWritinginPhysicsMeasurethelengthandperiodofthependulum,andusetheequationforthepage560periodofapendulumtosolveforg.63.HistoryofScienceResearchseveraldevicesthatwereusedintheseventeenth66.Asubmarinethatismoving12.0m/ssendsandeighteenthcenturiestostudystatic3Hzasonarpingoffrequency1.50�10electricity.ExamplesthatyoumighttowardaseamountthatisdirectlyinfrontofconsiderincludetheLeydenjarandthethesubmarine.Itreceivestheecho1.800sWimshurstmachine.Discusshowtheylater.(Chapter15)wereconstructedandhowtheyworked.a.HowfaristhesubmarinefromtheStudentanswerswillvary,butshouldseamount?includeinformationsuchasthefollow-ing.TheLeydenjar,inventedinthed�vt�(1533m/s)(0.900s)�1380mmid-1740s,wastheearliestcapacitor.Itb.Whatisthefrequencyofthesonarwavewasusedthroughouttheeighteenthandthatstrikestheseamount?nineteenthcenturiestostorechargesforv�v�d3Hz)electricity-relatedexperimentsandfd�fs��v�v�(1.50�10sdemonstrations.TheWimshurstmachine1533m/s�0.0m/swasadeviceusedinthenineteenthand�����1533m/s�12.0m/searlytwentiethcenturiestoproduceand�1510Hzdischargestaticcharges.Wimshurstmachines,whichwerereplacedbythec.WhatisthefrequencyoftheechoVandeGraaffgeneratorinthetwentiethreceivedbythesubmarine?century,usedLeydenjarstostorethechargespriortodischarge.v�vdf�d�fs��v�v�(1510Hz)s64.InChapter13,youlearnedthatforcesexist1533m/s�(�12.0m/s)betweenwatermoleculesthatcausewaterto�����1533m/s�0.0m/sbedenserasaliquidbetween0°Cand4°C�1520Hzthanasasolidat0°C.Theseforcesareelec-trostaticinnature.Researchelectrostaticinter-67.SecurityMirrorAsecuritymirrorisusedmolecularforces,suchasvanderWaalsforcestoproduceanimagethatisthree-fourthsanddipole-dipoleforces,anddescribetheirthesizeofanobjectandislocated12.0cmeffectsonmatter.behindthemirror.WhatisthefocallengthAnswerswillvary,butstudentsshouldofthemirror?(Chapter17)describetheinteractionsbetween�dipositiveandnegativechargesatthem���domolecularlevel.Studentsshould�dnotethatthestrengthoftheseforcesd��io�maccountsfordifferencesinmeltingandboilingpointsandfortheunusual�(�12.0cm)���behaviorofwaterbetween0°Cand4°C.�3�4CumulativeReview�16.0cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page560111��������65.Explainhowapendulumcanbeusedtofdodideterminetheaccelerationofgravity.dd(Chapter14)f��o�id�doiPhysics:PrinciplesandProblemsSolutionsManual425
429Chapter20continued(16.0cm)(�12.0cm)����ChallengeProblem16.0cm�(�12.0cm)page552��48.0cmAsshowninthefigurebelow,twospheresof68.A2.00-cm-tallobjectislocated20.0cmequalmass,m,andequalpositivecharge,q,awayfromadiverginglenswithafocalareadistance,r,apart.lengthof24.0cm.Whataretheimageposi-rtion,height,andorientation?Isthisarealoravirtualimage?(Chapter18)mass�mmass�m111charge�qcharge�q��������fddoi■Figure20-11dfod��i�d�f1.Deriveanexpressionforthecharge,q,thatomustbeoneachspheresothatthespheres(20.0cm)(�24.0cm)����areinequilibrium;thatis,sothatthe20.0cm�(�24.0cm)attractiveandrepulsiveforcesbetween��10.9cmthemarebalanced.hi�diTheattractiveforceisgravitation,andm������hodotherepulsiveforceiselectrostatic,sotheirexpressionsmaybesetequal.�dhioh��mqi�dAmBAqBoF���K���Fg�Gd2d2e�(�10.9cm)(2.00cm)����Themassesandchargesareequal,20.0cmandthedistancecancels,so�1.09cmGm2�Kq2,andThisisavirtualimagethatisuprightinorientation,relativetotheobject.Gq�m����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.K69.SpectrometerAspectrometercontainsa(6.67�10�11N�m2/kg2)gratingof11,500slits/cm.Findtheangle�m������(9.0�109N�m2/C2)atwhichlightofwavelength527nmhasafirst-orderbrightband.(Chapter19)�(8.61�10�11C/kg)mThenumberofcentimetersperslitis2.Ifthedistancebetweenthespheresisdou-theslitseparationdistance,d.bled,howwillthataffecttheexpressionfor�1slit�11,500slits/cmthevalueofqthatyoudeterminedinthedpreviousproblem?Explain.d�8.70�10�5cmThedistancedoesnotaffectthevalue��dsin�ofqbecausebothforcesareinverselyrelatedtothesquareofthedistance,�1���sin����andthedistancecancelsoutofthedexpression.�1527�10�9m�sin����8.70�10�3m3.Ifthemassofeachsphereis1.50kg,deter-�0.00347°minethechargeoneachsphereneededtomaintaintheequilibrium.q�(8.61�10�11C/kg)(1.50kg)�1.29�10�10C426SolutionsManualPhysics:PrinciplesandProblems
430CHAPTER21ElectricFieldsPracticeProblems��3.2�10�8CTheelectricforceisupward(opposite21.1CreatingandMeasuringthefield),sothechargeisnegative.ElectricFieldspages563–5685.Youareprobingtheelectricfieldofachargeofunknownmagnitudeandsign.Youfirstpage565�6Cisinanmapthefieldwitha1.0�10�6-Ctest1.Apositivetestchargeof5.0�10electricfieldthatexertsaforceof2.0�10�4Ncharge,thenrepeatyourworkwitha2.0�10�6-Ctestcharge.onit.Whatisthemagnitudeoftheelectricfieldatthelocationofthetestcharge?a.WouldyoumeasurethesameforcesatF2.0�10�4N1N/CthesameplacewiththetwotestE�������4.0�10q5.0�10�6Ccharges?Explain.No.Theforceonthe2.0-�Ccharge2.Anegativechargeof2.0�10�8Cexperi-wouldbetwicethatonthe1.0-�Cencesaforceof0.060Ntotherightinancharge.electricfield.Whatarethefield’smagnitudeb.Wouldyoufindthesamefieldanddirectionatthatlocation?strengths?Explain.F0.060N6N/CE��q������8C3.0�10Yes.Youwoulddividetheforceby2.0�10thestrengthofthetestcharge,sodirectedtothelefttheresultswouldbethesame.3.Apositivechargeof3.0�10�7Cislocatedinafieldof27N/Cdirectedtowardthepage566south.Whatistheforceactingonthecharge?6.WhatisthemagnitudeoftheelectricfieldFstrengthatapositionthatis1.2mfromaE���qpointchargeof4.2�10�6C?F�Eq�(27N/C)(3.0�10�7C)FqE����K��6Nq�d2�8.1�109N�m2/C2)(4.2�10�6C)�(9�10��4.Apithballweighing2.1�10�3Nisplaced(1.2m)2inadownwardelectricfieldof6.5�104N/C.�2.6�104N/CWhatcharge(magnitudeandsign)mustbeplacedonthepithballsothattheelectric7.Whatisthemagnitudeoftheelectricfieldforceactingonitwillsuspenditagainstthestrengthatadistancetwiceasfarfromtheforceofgravity?pointchargeinproblem6?TheelectricforceandthegravitationalBecausethefieldstrengthvariesastheforcealgebraicallysumtozerobecausesquareofthedistancefromthepointtheballissuspended,i.e.notinmotion:charge,thenewfieldstrengthwillbeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Fg�Fe�0,soFe��Fgone-fourthoftheoldfieldstrength,orF6.5�103N/C.E��e�q8.WhatistheelectricfieldatapositionthatFeFg2.1�10�3Nq��E����E����4N/Cis1.6meastofapointchargeof6.5�10�7.2�10�6C?Physics:PrinciplesandProblemsSolutionsManual427
431Chapter21continuedFqTodetectafieldatapoint,placeatestE����K�q�d2chargeatthatpointanddetermineif9N�m2/C2)(7.2�10�6C)thereisaforceonit.�(9.0�10��(1.6m)2Todeterminethemagnitudeofthefield,�2.5�104N/CdividethemagnitudeoftheforceonthetestchargebythemagnitudeofthetestThedirectionofthefieldiseast(awaycharge.fromthepositivepointcharge).Themagnitudeofthetestchargemust9.Theelectricfieldthatis0.25mfromabechosensothatitisverysmallcom-smallsphereis450N/Ctowardthesphere.paredtothemagnitudesofthechargesWhatisthechargeonthesphere?producingthefield.FqThenextthingyoushoulddoismea-E����K�q�d2surethedirectionoftheforceonthe2testcharge.ThedirectionofthefieldisEdq��thesameasthedirectionoftheforceifK2thetestchargeispositive;otherwise,it�����(450N/C)(0.25m)�3.1�10�9C(9.0�109N�m2/C2)isintheoppositedirection.Thechargeisnegative,becausethe12.FieldStrengthandDirectionApositivefieldisdirectedtowardit.testchargeofmagnitude2.40�10�8C�6Cexperiencesaforceof1.50�10�3Ntoward10.Howfarfromapointchargeof�2.4�10theeast.Whatistheelectricfieldatthemustatestchargebeplacedtomeasureapositionofthetestcharge?fieldof360N/C?F1.50�10�3NeastF��K�qE�������E��q�d2q2.40�10�8C�6.25�104N/CeastKqd�����E13.FieldLinesInFigure21-4,canyoutellCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(9.0�109N�m2/C2)(2.4�10�6C)whichchargesarepositiveandwhichare���������360N/Cnegative?Whatwouldyouaddtocomplete�7.7mthefieldlines?No.Thefieldlinesmusthavearrow-headsindicatingtheirdirections,fromSectionReviewpositivetonegativecharges.21.1CreatingandMeasuring14.FieldVersusForceHowdoestheelectricElectricFieldsfield,E,atthetestchargedifferfromthepages563–568force,F,onit?page568Thefieldisapropertyofthatregionof11.MeasuringElectricFieldsSupposeyouarespace,anddoesnotdependonthetestaskedtomeasuretheelectricfieldinspace.chargeusedtomeasureit.TheforceHowdoyoudetectthefieldatapoint?Howdependsonthemagnitudeandsignofdoyoudeterminethemagnitudeofthethetestcharge.field?Howdoyouchoosethemagnitudeofthetestcharge?Whatdoyoudonext?15.CriticalThinkingSupposethetopchargeinFigure21-2cisatestchargemeasuringthefieldresultingfromthetwonegativecharges.Isitsmallenoughtoproduceanaccuratemeasure?Explain.428SolutionsManualPhysics:PrinciplesandProblems
432Chapter21continuedNo.Thischargeislargeenoughtopage572distortthefieldproducedbytheother21.Whatworkisdonewhen3.0Cismovedchargeswithitsownfield.ComparethroughanelectricpotentialdifferencewithFigure21-4b.of1.5V?W�q�V�(3.0C)(1.5V)�4.5JPracticeProblems22.A12-Vcarbatterycanstore1.44�106Cwhenitisfullycharged.Howmuchwork21.2ApplicationsofcanbedonebythisbatterybeforeitneedsElectricFieldsrecharging?pages569–579W�q�V�(1.44�106C)(12V)page571�1.7�107J16.Theelectricfieldintensitybetweentwolarge,charged,parallelmetalplatesis23.Anelectroninatelevisionpicturetube6000N/C.Theplatesare0.05mapart.passesthroughapotentialdifferenceofWhatistheelectricpotentialdifference18,000V.Howmuchworkisdoneonthebetweenthem?electronasitpassesthroughthatpotential�V�Ed�(6000N/C)(0.05m)difference?�300J/C�3�102VW�q�V�(1.60�10�19C)(1.8�104V)�2.9�10�15J17.Avoltmeterreads400Vacrosstwocharged,parallelplatesthatare0.020mapart.What24.Ifthepotentialdifferenceinproblem18isistheelectricfieldbetweenthem?betweentwoparallelplatesthatare2.4cm�V�Edapart,whatisthemagnitudeoftheelectricE���V���400V2�104N/Cfieldbetweenthem?�d0.020m�V5.00�102V4N/CE�������2.1�10d0.024m18.Whatelectricpotentialdifferenceisappliedtotwometalplatesthatare0.200mapart25.Theelectricfieldinaparticle-acceleratoriftheelectricfieldbetweenthemis5N/C.Howmuchworkmachineis4.5�102.50�103N/C?isdonetomoveaproton25cmthrough�V�Ed�(2.50�103N/C)(0.200m)thatfield?�5.00�102VW�q�V�qEd�(1.60�10�19C)(4.5�105N/C)(0.25m)19.Whenapotentialdifferenceof125Visappliedtotwoparallelplates,thefield�1.8�10�14Jbetweenthemis4.25�103N/C.Howfarapartaretheplates?page574�V�Ed26.AdropisfallinginaMillikanoil-dropappa-d���V����125V2.94�10�2mratuswithnoelectricfield.Whatforcesare�E4.25�103N/Cactingontheoildrop,regardlessofitsaccel-eration?Ifthedropisfallingataconstant20.Apotentialdifferenceof275VisappliedtoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.velocity,describetheforcesactingonit.twoparallelplatesthatare0.35cmapart.Gravitationalforce(weight)downward,Whatistheelectricfieldbetweentheplates?frictionforceofairupward.Thetwo�V275V4N/CforcesareequalinmagnitudeiftheE�������7.9�10d3.5�10�3mdropfallsatconstantvelocity.Physics:PrinciplesandProblemsSolutionsManual429
433Chapter21continued27.Anoildropweighs1.9�10�15N.Itissus-32.Thesametwocapacitorsasinproblem31pendedinanelectricfieldof6.0�103N/C.areeachchargedto3.5�10�4C.WhichhasWhatisthechargeonthedrop?Howmanythelargerelectricpotentialdifferenceacrossexcesselectronsdoesitcarry?it?Whatisit?Fqg�Eq�V���,sothesmallercapacitorhasCFg1.9�10�15Nthelargerpotentialdifference.q�����E6.0�103N/C3.5�10�4C2V�V����1.1�10�19C3.5�10�6F�3.2�10q3.2�10�19C33.A2.2-�Fcapacitorfirstischargedsothat#electrons�������2qe1.60�10�19Ctheelectricpotentialdifferenceis6.0V.Howmuchadditionalchargeisneededto28.Anoildropcarriesoneexcesselectronandincreasetheelectricpotentialdifferencetoweighs6.4�10�15N.Whatelectricfield15.0V?strengthisrequiredtosuspendthedropsoq�C�Vitismotionless?F6.4�10�15N�q�C(�V2��V1)E�������4.0�104N/C�6F)(15.0V�6.0V)q1.60�10�19C�(2.2�10�2.0�10�5C29.Apositivelychargedoildropweighing1.2�10�14Nissuspendedbetweenparallel34.Whenachargeof2.5�10�5Cisaddedtoaplatesseparatedby0.64cm.Thepotentialcapacitor,thepotentialdifferenceincreasesdifferencebetweentheplatesis240V.Whatfrom12.0Vto14.5V.Whatisthecapaci-isthechargeonthedrop?Howmanyelec-tanceofthecapacitor?tronsisthedropmissing?q2.5�10�5CC������E���V����240V3.8�104N/C�V2��V114.5V�12.0V�d6.4�10�3m�1.0�10�5FFE���Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.qF1.2�10�14N�19Cq��E�����4N/C3.2�10SectionReview3.8�10q3.4�10�19C21.2Applicationsof#electrons�������2qe1.60�10�19CElectricFieldspages569–579page578page57930.A27-�Fcapacitorhasanelectricpotential35.PotentialDifferenceWhatisthediffer-differenceof45Vacrossit.Whatistheencebetweenelectricpotentialenergyandchargeonthecapacitor?electricpotentialdifference?q�C�V�(27�10�6F)(45V)Electricpotentialenergychangeswhen�1.2�10�3Cworkisdonetomoveachargeinanelectricfield.Itdependsontheamountofchargeinvolved.Electricpotential31.Botha3.3-�Fanda6.8-�Fcapacitoraredifferenceistheworkdoneperunitconnectedacrossa24-Velectricpotentialchargetomoveachargeinanelectricdifference.Whichcapacitorhasagreaterfield.Itisindependentoftheamountofcharge?Whatisit?chargethatismoved.q�C�V,sothelargercapacitorhasagreatercharge.q�(6.8�10�6F)(24V)�1.6�10�4C430SolutionsManualPhysics:PrinciplesandProblems
434Chapter21continued36.ElectricFieldandPotentialDifferenceThechargesonthemetaldomepro-Showthatavoltpermeteristhesameasaducenofieldinsidethedome.Thenewtonpercoulomb.chargesfromthebeltaretransferredV/m�J/C�m�N�m/C�m�N/Cimmediatelytotheoutsideofthedome,wheretheyhavenoeffectonnew37.MillikanExperimentWhenthechargeonchargesarrivingatpointB.anoildropsuspendedinaMillikanappara-tusischanged,thedropbeginstofall.HowshouldthepotentialdifferenceontheChapterAssessmentplatesbechangedtobringthedropbackConceptMappingintobalance?page584Thepotentialdifferenceshouldbe42.Completetheconceptmapbelowusingtheincreased.followingterms:capacitance,fieldstrength,J/C,work.38.ChargeandPotentialDifferenceInproblem37,ifchangingthepotentialdif-ferencehasnoeffectonthefallingdrop,ElectricFieldwhatdoesthistellyouaboutthenewchargeonthedrop?forceworkThedropiselectricallyneutral(noelectronexcessordeficiency).testcharge39.CapacitanceHowmuchchargeisstoredfieldpotentialona0.47-�Fcapacitorwhenapotentialstrengthdifferencedifferenceof12Visappliedtoit?q�C�V�(4.7�10�7F)(12V)capacitance�5.6�10�6CN/CJ/C40.ChargeSharingIfalarge,positivelycharged,conductingsphereistouchedbyasmall,negativelycharged,conductingsphere,C/Vwhatcanbesaidaboutthefollowing?a.thepotentialsofthetwospheresMasteringConceptsThesphereswillhaveequalpage584potentials.43.Whatarethetwopropertiesthatatestb.thechargesonthetwosphereschargemusthave?(21.1)ThelargespherewillhavemoreThetestchargemustbesmallinmag-chargethanthesmallsphere,butnituderelativetothemagnitudesofthetheywillbethesamesign.Thesignchargesproducingthefieldandbeofthechargewilldependonwhichpositive.spherebeganwithmorecharge.44.Howisthedirectionofanelectricfield41.CriticalThinkingReferringbacktodefined?(21.1)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Figure21-3a,explainhowchargecontinuesThedirectionofanelectricfieldisthetobuilduponthemetaldomeofaVandedirectionoftheforceonapositiveGraaffgenerator.Inparticular,whyisn’tchargeplacedinthefield.ThiswouldchargerepelledbackontothebeltatpointB?beawayfromapositiveobjectandtowardanegativeobject.Physics:PrinciplesandProblemsSolutionsManual431
435Chapter21continued45.Whatareelectricfieldlines?(21.1)48.InFigure21-15,wheredotheelectricfieldlinesofforcelinesleavethepositivechargeend?(21.1)46.Howisthestrengthofanelectricfieldindi-catedwithelectricfieldlines?(21.1)Theclosertogethertheelectricfieldlinesare,thestrongertheelectricfield.�47.Drawsomeoftheelectricfieldlinesbetweeneachofthefollowing.(21.1)a.twolikechargesofequalmagnitude■ Figure21-15Theyendondistantnegativechargessomewherebeyondtheedgesofthediagram.b.twounlikechargesofequalmagnitude49.WhatSIunitisusedtomeasureelectricpotentialenergy?WhatSIunitisusedtomeasureelectricpotentialdifference?(21.2)electricpotentialenergy:joule;electricpotential:voltc.apositivechargeandanegativechargehavingtwicethemagnitudeoftheposi-50.Definevoltintermsofthechangeinpoten-tivechargetialenergyofachargemovinginanelectricfield.(21.2)Avoltisthechangeinelectricpotentialenergy,�PE,resultingfrommovingaunittestcharge,q,adistance,d,ofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1minanelectricfield,E,of1N/C.�V��PE/q�Ed��51.Whydoesachargedobjectloseitschargewhenitistouchedtotheground?(21.2)ThechargeissharedwiththesurfaceofEarth,whichisanextremelylargeobject.52.Achargedrubberrodthatisplacedonatablemaintainsitschargeforsometime.d.twooppositelychargedparallelplatesWhyisthechargedrodnotdischargedimmediately?(21.2)��Thetableisaninsulator,oratleasta��verypoorconductor.����53.Ametalboxischarged.Comparethecon-��centrationofchargeatthecornersofthe��boxtothechargeconcentrationonthesidesofthebox.(21.2)Theconcentrationofchargeisgreateratthecorners.432SolutionsManualPhysics:PrinciplesandProblems
436Chapter21continued54.ComputersEDDelicatepartsinelectronicequipment,x�CsuchasthosepicturedinABFigure21-16,arecontainedwithinametaly��zboxinsidea■ Figure21-17plasticcase.■ Figure21-16Why?(21.2)SpherexwillfollowpathC.ItwillThemetalboxshieldsthepartsfromexperienceforcesshownbyDandB.externalelectricfields,whichdonotThevectorsumisC.existinsideahollowconductor.59.Whatistheunitofelectricpotentialdiffer-ApplyingConceptsenceintermsofm,kg,s,andC?pages584–585V�J/C�N�m/C�(kg�m/s2)(m/C)55.Whathappenstothestrengthofanelectric�kg�m2/s2�Cfieldwhenthechargeonthetestchargeishalved?60.WhatdotheelectricfieldlineslooklikeNothing.Becausetheforceonthetestwhentheelectricfieldhasthesamechargealsowouldbehalved,theratiostrengthatallpointsinaregion?F�/q�andtheelectricfieldwouldremainTheyareparallel,equallyspacedlines.thesame.61.MillikanOil-DropExperimentWhen56.DoesitrequiremoreenergyorlessenergydoingaMillikanoil-dropexperiment,itistomoveaconstantpositivechargethroughbesttoworkwithdropsthathavesmallanincreasingelectricfield?charges.Therefore,whentheelectricfieldisturnedon,shouldyoutrytofinddropsthatEnergyisproportionaltotheforce,andaremovingrapidlyorslowly?Explain.theforceisproportionaltotheelectricfield.Therefore,itrequiresmoreenergy.Slowly.Thelargerthecharge,thestrongertheforce,andthus,thelarger57.Whatwillhappentotheelectricpotentialthe(terminal)velocity.energyofachargedparticleinanelectricfieldwhentheparticleisreleasedandfree62.Twooildropsareheldmotionlessinatomove?Millikanoil-dropexperiment.Theelectricpotentialenergyofthea.Canyoubesurethatthechargesaretheparticlewillbeconvertedintokineticsame?energyoftheparticle.No.Theirmassescouldbedifferent.b.Theratiosofwhichtwopropertiesof58.Figure21-17showsthreesphereswiththeoildropshavetobeequal?chargesofequalmagnitude,withtheirchargetomassratio,q/m(orm/q)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.signsasshown.Spheresyandzareheldinplace,butspherexisfreetomove.63.JoséandSuearestandingonaninsulatingInitially,spherexisequidistantfromplatformandholdinghandswhentheyarespheresyandz.Choosethepaththatgivenacharge,asinFigure21-18.Joséisspherexwillbegintofollow.AssumethatlargerthanSue.Whohasthelargeramountnootherforcesareactingonthespheres.ofcharge,ordotheybothhavethesameamount?Physics:PrinciplesandProblemsSolutionsManual433
437Chapter21continuedF0.30N4N/CE�������3.0�10q1.0�10�5Cinthesamedirectionastheforce68.Atestchargeexperiencesaforceof0.30Nonitwhenitisplacedinanelectricfieldintensityof4.5�105N/C.Whatisthemag-nitudeofthecharge?FE���q■ Figure21-18F0.30N�7Cq�������6.7�10E4.5�105N/CJoséhasalargersurfacearea,sohewillhavealargeramountofcharge.69.Theelectricfieldintheatmosphereisabout150N/Cdownward.64.Whichhasalargercapacitance,analu-a.Whatisthedirectionoftheforceonaminumspherewitha1-cmdiameteroronenegativelychargedparticle?witha10-cmdiameter?upwardThe10-cmdiameterspherehasalargerb.Findtheelectricforceonanelectroncapacitancebecausethechargescanwithcharge�1.6�10�19C.befartherapart,reducingpotentialriseasitischarged.E�F��q65.HowcanyoustoredifferentamountsofF�qE�(1.6�10�19C)(150N/C)chargeinacapacitor?�2.4�10�17NChangethevoltageacrossthecapacitor.F�2.4�10�17NdirectedupwardMasteringProblemsc.ComparetheforceinpartbwiththeforceofgravityonthesameelectronCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.21.1CreatingandMeasuringElectricFields(mass�9.1�10�31kg).pages585–586�19C.F�mg�(9.1�10�31kg)(9.80m/s2)Thechargeofanelectronis�1.60�10Level1�8.9�10�30N66.WhatchargeexistsonatestchargethatF�8.9�10�30N(downward),moreexperiencesaforceof1.4�10�8Natathanonetrilliontimessmallerpointwheretheelectricfieldintensityis5.0�10�4N/C?70.Carefullysketcheachofthefollowing.Fa.theelectricfieldproducedbya�1.0-�CE���qchargeF1.4�10�8N�5Cq�������2.8�10E5.0�10�4N/C67.Apositivechargeof1.0�10�5C,showninFigure21-19,0.30N�1.0�Cexperiencesaforceof0.30Nwhenitislocatedatacertain1.0�10�5Cpoint.Whatistheelectricfieldintensityatthatpoint?■ Figure21-19434SolutionsManualPhysics:PrinciplesandProblems
438Chapter21continuedb.theelectricfieldresultingfroma�2.0-�Cb.ChargeZnowhasasmallpositivecharge(Makethenumberoffieldlineschargeonit.Drawanarrowrepresent-proportionaltothechangeincharge.)ingtheforceonit.F�2.0�CFyFxZ71.Apositivetestchargeof6.0�10�6Cis73.Inatelevisionpicturetube,electronsareplacedinanelectricfieldof50.0-N/Cacceleratedbyanelectricfieldhavingaintensity,asinFigure21-20.Whatisthevalueof1.00�105N�C.strengthoftheforceexertedonthetesta.Findtheforceonanelectron.charge?FE���qq�6.0�10�6CF�Eq�(�1.60�10�19C)(1.00�105N/C)��1.60�10�14Nb.Ifthefieldisconstant,findtheE�50.0N/Caccelerationoftheelectron■ Figure21-20(mass�9.11�10�31kg).FF�maE���qF�1.60�10�14NF�qE�(6.0�10�6C)(50.0N/C)a��m����9.11�10�31kg�3.0�10�4N��1.76�1016m/s2Level274.Whatistheelectricfieldstrength20.0cm72.ChargesX,Y,andZallareequidistantfromfromapointchargeof8.0�10�7C?eachother.Xhasa�1.0-�Ccharge,YhasaFKqq�E��,andF���2.0-�Ccharge,andZhasasmallnegativeq�d2charge.KqsoE��a.Drawanarrowrepresentingtheforceond2chargeZ.(9.0�109N�m2/C2)(8.0�10�7C)�����(0.200m)2ZFx�1.8�105N/CFyCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.FXYPhysics:PrinciplesandProblemsSolutionsManual435
439Chapter21continued75.Thenucleusofaleadatomhasachargeof78.Anelectronismovedthroughanelectric82protons.potentialdifferenceof450V.Howmucha.Whatarethedirectionandmagnitudeworkisdoneontheelectron?oftheelectricfieldat1.0�10�10mW�V���fromthenucleus?qQ�(82protons)W�q�V(1.60�10�19C/proton)�(�1.60�10�19C)(450V)�1.31�10�17C��7.2�10�17JF1KqQKQE��q���q����2��279.A12-Vbatterydoes1200Jofworkddtransferringcharge.Howmuchcharge(9.0�109N�m2/C2)(1.31�10�17C)istransferred?�����(1.0�10�10m)2W�1.2�1013N/C,outward�V���qb.WhatarethedirectionandmagnitudeW1200J2Cq�������1.0�10oftheforceexertedonanelectron�V12Vlocatedatthisdistance?80.TheelectricfieldintensitybetweentwoF�Eq3N/C.Theplateschargedplatesis1.5�10�(1.2�1013N/C)(�1.60�10�19C)are0.060mapart.Whatistheelectric��1.9�10�6N,towardthenucleuspotentialdifference,involts,betweentheplates?�V�Ed21.2ApplicationsofElectricFieldspages586–587�(1.5�103N/C)(0.060m)Level1�9.0�101V76.If120Jofworkisperformedtomove2.4Cofchargefromthepositiveplatetothenega-81.AvoltmeterindicatesthattheelectricCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tiveplateshowninFigure21-21,whatpotentialdifferencebetweentwoplatesispotentialdifferenceexistsbetweentheplates?70.0V.Theplatesare0.020mapart.Whatelectricfieldintensityexistsbetweenthem?���V�Ed��2.4C���V70.0VE�������3500V/m��d0.020m���3500N/C����82.Acapacitorthatisconnectedtoa45.0-Vsourcecontains90.0�Cofcharge.Whatis■ Figure21-21thecapacitor’scapacitance?W120J1V�V��q���2.4�C�5.0�10q90.0�10�6CC�������2.00µF�V45.0V77.Howmuchworkisdonetotransfer0.15C83.Whatelectricpotentialdifferenceexistsofchargethroughanelectricpotentialdif-acrossa5.4-�Fcapacitorthathasachargeferenceof9.0V?of8.1�10�4C?W�V���qqC����VW�q�V�(0.15C)(9.0V)�1.4Jq8.1�10�4C�V�����C5.4�10�6F�1.5�102V436SolutionsManualPhysics:PrinciplesandProblems
440Chapter21continued84.TheoildropshowninFigure21-22isneg-87.PhotoflashTheenergystoredinacapaci-ativelychargedandweighs4.5�10�15N.torwithcapacitanceC,andanelectricThedropissuspendedinanelectricfieldpotentialdifference,�V,isrepresentedbyintensityof5.6�103N/C.W��1�C�V2.Oneapplicationofthisisin2��������theelectronicphotoflashofastrobelight,liketheoneinFigure21-24.Insuchaunit,acapacitorof10.0�Fischargedto3.0�102V.Findtheenergystored.8.5�10�15N�������■ Figure21-22a.Whatisthechargeonthedrop?FE���qF4.5�10�15Nq������E5.6�103N/C■ Figure21-24�8.0�10�19CW��1�C�V22b.Howmanyexcesselectronsdoesitcarry?���1��(10.0�10�6F)(3.0�102V)2(8.0�10�19C)����1electron21.60�10�19C�0.45J�5electrons88.Supposeittook25stochargethecapacitor85.Whatisthechargeona15.0-pFcapacitorinproblem87.whenitisconnectedacrossa45.0-Vsource?a.FindtheaveragepowerrequiredtoqC����Vchargethecapacitorinthistime.q�C�V�(15.0�10�12F)(45.0V)P��W���0.45�J�1.8�10�2Wt25s�6.75�10�10Cb.Whenthiscapacitorisdischargedthroughthestrobelamp,ittransfersallLevel2itsenergyin1.0�10�4s.Findthe86.Aforceof0.065Nisrequiredtomoveapowerdeliveredtothelamp.chargeof37�Cadistanceof25cminauniformelectricfield,asinFigure21-23.P�W�����0.45J4.5�103W�t1.0�10�4sWhatisthesizeoftheelectricpotentialdifferencebetweenthetwopoints?c.Howissuchalargeamountofpowerpossible?37�CPowerisinverselyproportionalto0.053Nthetime.Theshorterthetimeforagivenamountofenergytobe25cmexpended,thegreaterthepower.■ Figure21-23Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.W�FdWFdand�V������qq(0.065N)(0.25m)����37�10�6C�4.4�102VPhysics:PrinciplesandProblemsSolutionsManual437
441Chapter21continued89.LasersLasersareusedtotrytoproducebetweenthemis300V,whatisthecapaci-controlledfusionreactions.Theselaserstanceofthesystem?requirebriefpulsesofenergythatarestored0.060�C�0.060�Cinlargeroomsfilledwithcapacitors.One��suchroomhasacapacitanceof61�10�3F�����V�300Vchargedtoapotentialdifferenceof10.0kV.������12,findtheenergya.GiventhatW���C�V25cm2storedinthecapacitors.■ Figure21-25W��1�C�V2q6.0�10�8C�10F2C�������2�10�V300V���1��(61�10�3F)(1.00�104V)2293.Theplatesofa0.047�Fcapacitorare�3.1�106J0.25cmapartandarechargedtoapoten-tialdifferenceof120V.Howmuchchargeb.Thecapacitorsaredischargedin10ns(1.0�10�8s).Whatpowerisproduced?isstoredonthecapacitor?q6JC���W3.1�1014W�VP�������3.1�10t1.0�10�8sq�C�Vc.Ifthecapacitorsarechargedbyagener-�(4.7�10�8F)(120V)atorwithapowercapacityof1.0kW,howmanysecondswillberequiredto�5.6�10�6C�5.6�Cchargethecapacitors?6J94.WhatisthestrengthoftheelectricfieldW3.1�103st��P�����3W3.1�10betweentheplatesofthecapacitorin1.0�10Problem93above?MixedReview�V�Edpage587�VE���Level1dCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.90.Howmuchworkdoesittaketomove����120V4.8�104V/m0.25�Cbetweentwoparallelplatesthat2.5�10�3mare0.40cmapartifthefieldbetweenthe95.Anelectronisplacedbetweentheplatesofplatesis6400N/C?thecapacitorinProblem93above,asinW�q�V�qEdFigure21-26.Whatforceisexertedonthat�(2.5�10�7C)(6400N/C)(4.0�10�3m)electron?�6.4�10�6J�V�120V��C�0.047�F91.Howmuchchargeisstoredona0.22-�F��parallelplatecapacitoriftheplatesare1.2cmapartandtheelectricfieldbetween��themis2400N/C?��q�C�V�CEd���7F)(2400N/C)(1.2�10�2m)�(2.2�10���6.3�C0.25cm■ Figure21-2692.Twoidenticalsmallspheres,25cmapart,carryequalbutoppositechargesof0.060�C,asinFigure21-25.Ifthepotentialdifference438SolutionsManualPhysics:PrinciplesandProblems
442Chapter21continuedF1E���W�area���bhq2F�Eq���1��(25V)(12.5�C)2�(4.8�104V/m)(1.6�10�19C)�160�J�7.7�10�15N101.TheworkfoundinProblem100aboveis96.Howmuchworkwouldittaketomoveannotequaltoq�V.Whynot?additional0.010�CbetweentheplatesatThepotentialdifferenceisnotcon-120VinProblem93?stantasthecapacitorischarged.WTherefore,theareaunderthegraph�V���qmustbeusedtofindwork,notjustW�q�Vsimplemultiplication.�(1.0�10�8C)(120V)�1.2�10�6J102.GraphtheelectricfieldstrengthnearapositivepointchargeasafunctionofLevel2distancefromit.97.ThegraphinFigure21-27representsthechargestoredinacapacitorasthechargingpotentialincreases.Whatdoestheslopeofthelinerepresent?ChargeStoredEonCapacitor15C)d�10(q103.Whereisthefieldofapointchargeequal5tozero?0Nowhere,orataninfinitedistance102030fromthepointcharge.�V(V)■Figure21-27104.Whatistheelectricfieldstrengthatadis-capacitanceofthecapacitortanceofzerometersfromapointcharge?Istheresuchathingasatruepointcharge?98.WhatisthecapacitanceofthecapacitorInfinite.No.representedbyFigure21-27?C�slope�0.50�FThinkingCriticallypages587–58899.Whatdoestheareaunderthegraphlinein105.ApplyConceptsAlthoughalightningrodFigure21-27represent?isdesignedtocarrychargesafelytotheworkdonetochargethecapacitorground,itsprimarypurposeistopreventlightningfromstrikinginthefirstplace.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.100.HowmuchworkisrequiredtochargetheHowdoesitdothat?capacitorinproblem98toapotentialdif-Thesharppointontheendoftherodferenceof25V?leakschargeintotheatmospherebeforeithasthechancetobuildupenoughpotentialdifferencetocausealightningstrike.Physics:PrinciplesandProblemsSolutionsManual439
443Chapter21continued106.AnalyzeandConcludeInanearlysetofexperimentsin1911,Millikanobservedthatthefollowingmeasuredchargescouldappearonasingleoildrop.Whatvalueofelementarychargecanbededucedfromthesedata?a.6.563�10�19Cf.18.08�10�19Cb.8.204�10�19Cg.19.71�10�19Cc.11.50�10�19Ch.22.89�10�19Cd.13.13�10�19Ci.26.13�10�19Ce.16.48�10�19C1.63�1019C.Subtractingadjacentvalues,b�a,c�b,d�c,etc.yields1.641�10�19C,3.30�10�19C,1.63�10�19C,3.35�10�19C,1.60�10�19C,1.63�10�19C,3.18�10�19C,3.24�10�19C.Therearetwonumbers,approximately1.631�10�19Cand3.2�10�19C,thatarecommon.Averagingeachsimilargroupproducesonechargeof1.63�10�19Candonechargeof3.27�10�19C(whichistwotimes1.641�10�19C).Dividing1.63�10�19Cintoeachpieceofdatayieldsnearlywhole-num-berquotients,indicatingitisthevalueofanelementarycharge.107.AnalyzeandConcludeTwosmallspheres,AandB,lieonthex-axis,asinFigure21-28.SphereAhasachargeof�3.00�10�6C.SphereBis0.800mtotherightofsphereAandhasachargeof�5.00�10�6C.Findthemagnitudeanddirectionoftheelectricfieldstrengthatapointabovethex-axisthatwould�3.00�10�6C�5.00�10�6CformtheapexofanequilateraltrianglewithABspheresAandB.0.800mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Drawthespheresandvectorsrepresenting■ Figure21-28thefieldsduetoeachchargeatthegivenpoint.EAEREB0.800mABNowdothemath:FAKqA(9.0�109N�m2/C2)(3.00�10�6C)4N/CE������A���q�d2(0.800m)2�4.22�10FBKqB(9.0�109N�m2/C2)(5.00�10�6C)4N/CE������B���q�d2(0.800m)2�7.03�10E4N/C)(cos60.0°)�2.11�104N/CAx�EAcos60.0°�(4.22�10E4N/C)(sin60.0°)�3.65�104N/CAy�EAsin60.0°�(4.22�10440SolutionsManualPhysics:PrinciplesandProblems
444Chapter21continuedE4N/C)(cos�60.0°)�3.52�104N/CBx�EBcos(�60.0°)�(7.03�10E4N/C)(sin�60.0°)��6.09�104N/CBy�EBsin(�60.0°)�(7.03�10E4N/C)�(3.52�104N/C)�5.63�104N/Cx�EAx�EBx�(2.11�10E4N/C)�(�6.09�104N/C)��2.44�104N/Cy�EAy�EBy�(3.65�10ER���Ex2��Ey2�6.14�104N/CEytan���ExE�1y��tan���Ex�1�2.44�104N/C�tan�����4N/C5.63�10��23.4°108.AnalyzeandConcludeInanink-jetprinter,dropsof1.5cminkaregivenacertainamountofchargebeforetheymovebetweentwolarge,parallelplates.ThepurposeoftheplatesistodeflectthechargessothattheyareqGutterstoppedbyagutteranddonotreachthepaper.ThisisshowninFigure21-29.Theplatesare1.5-cmlongmvandhaveanelectricfieldofE�1.2�106N/CbetweenE�1.2�106N/Cthem.Dropswithamassm�0.10ng,andacharge■ Figure21-29q�1.0�10�16C,aremovinghorizontallyataspeed,v�15m/s,paralleltotheplates.Whatistheverticaldisplacementofthedropswhentheyleavetheplates?Toanswerthisquestion,completethefollowingsteps.a.Whatistheverticalforceonthedrops?F�Eq�(1.0�10�16C)(1.2�106N/C)�1.2�10�10Nb.Whatistheirverticalacceleration?F1.2�10�10N3m/s2a�������1.2�10m1.0�10�13kgc.Howlongaretheybetweentheplates?L1.5�10�2m�3st�������1.0�10v15m/sd.Howfararetheydisplaced?12y���at2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.���1��3m/s2)(1.0�10�3s)2(1.2�102�6.0�10�4m�0.60mmPhysics:PrinciplesandProblemsSolutionsManual441
445Chapter21continued109.ApplyConceptsSupposetheMoonhadanetnegativechargeequalto�q,andEarthhadanetpositivechargeequalto�10q.Whatvalueofqwouldyieldthesamemagnitudeofforcethatyounowattributetogravity?EquatetheexpressionsforgravitationalforceandCoulombicforcebetweenEarthandtheMoon:GmKq10Kq2F�����EmM�EqM�d2d2d2where�qisthenetnegativechargeoftheMoonandqE,thenetpositivechargeofEarth,is�10q.Solvesymbolicallybeforesubstitutingnumbers.Gmq�����EmM10K(6.67�10�11N�m2/kg2)(6.00�1024kg)(7.31�1022kg)�������������(10)(9.0�109N�m2/C2)�1.8�1013CWritinginPhysicspage588110.Choosethenameofanelectricunit,suchascoulomb,volt,orfarad,andresearchthelifeandworkofthescientistforwhomitwasnamed.Writeabriefessayonthispersonandincludeadiscussionoftheworkthatjustifiedthehonorofhavingaunitnamedforhim.Studentanswerswillvary.SomeexamplesofscientiststheycouldchooseareVolta,Coulomb,Ohm,andAmpère.CumulativeReviewCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page588111.Michelsonmeasuredthespeedoflightbysendingabeamoflighttoamirroronamountain35kmaway.(Chapter16)a.Howlongdoesittakelighttotravelthedistancetothemountainandback?(35km/trip)(2trips)(1000m/1km)/3.00�108m/s�2.3�10�4sb.AssumethatMichelsonusedarotatingoctagonwithamirroroneachfaceoftheoctagon.Alsoassumethatthelightreflectsfromonemirror,travelstotheothermountain,reflectsoffofafixedmirroronthatmountain,andreturnstotherotatingmirrors.Iftherotatingmirrorhasadvancedsothatwhenthelightreturns,itreflectsoffofthenextmirrorintherotation,howfastisthemirrorrotating?2.3�10�4s�3s/rev�T����(8mirrors/rev)�1.8�101mirror112rev/sf������5.6�10T1.8�10�3s/revNotethatifstudentscarryextradigitsfrompartatopreventround-ingerrors,theywillgetananswerof5.4�102rev/s.442SolutionsManualPhysics:PrinciplesandProblems
446Chapter21continuedc.Ifeachmirrorhasamassof1.0�101ghyouhmountain����androtatesinacirclewithanaveragedyoudmountainradiusof1.0�101cm,whatisthehyoudmountainapproximatecentripetalforceneededh��mountain�dyoutoholdthemirrorwhileisitrotating?F�2mf2r��(2m)(50,�000m)c�450m�4�2(0.010kg)(5.6�102rev/s)2�2000m(0.10m)113.Aconverginglenshasafocallengthof�1.2�104N38.0cm.Ifitisplaced60.0cmfromanobject,atwhatdistancefromthelenswillNotethattheanswershouldbetheimagebe?(Chapter18)1.2�104Nregardlessofwhether111thestudentsuse5.4�102rev/sor�������fdd5.6�104rev/sforf.oidd�ofi�d112.MountainSceneYoucanseeanimageofo�fadistantmountaininasmoothlakejust(60.0cm)(38.0cm)����asyoucanseeamountainbikernextto60.0cm�38.0cmthelakebecauselightfromeachstrikesthe�104cmsurfaceofthelakeataboutthesameangleTheimageis104cmfromthelens.ofincidenceandisreflectedtoyoureyes.Ifthelakeisabout100mindiameter,the114.Aforce,F,ismeasuredbetweentworeflectionofthetopofthemountainischarges,Qandq,separatedbyadistance,aboutinthemiddleofthelake,themoun-r.Whatwouldthenewforcebeforeachoftainisabout50kmawayfromthelake,thefollowing?(Chapter20)andyouareabout2mtall,thenapproxi-a.ristripledmatelyhowhighabovethelakedoesthetopofthemountainreach?(Chapter17)F/9Sincetheangleofincidenceoftheb.Qistripledlightfromthetopofthemountainis3Fequaltoitsangleofreflectionfromthec.bothrandQaretripledlake,youandthereflectionofthetopF/3ofthemountainformatrianglethatissimilartoatriangleformedbythed.bothrandQaredoubledmountainandthetopofitsreflectionF/2inthelake.Yourheightmakesuponee.allthree,r,Q,andq,aretripledside,hyou�2mandthetopoftheFmountainishalfwayacrossthelake,dyou�50m.Themountainisadis-tancedmountain�50,000mfromitsreflection.FindhmountainbyequatingtheratiosofthesidesofthetwoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.similartriangles.Physics:PrinciplesandProblemsSolutionsManual443
447Chapter21continuedChallengeProblempage579Theplatesofacapacitorattracteachotherbecausethey��carryoppositecharges.Acapacitorconsistingoftwoparallel��platesthatareseparatedbyadistance,d,hascapacitance,C.������1.Deriveanexpressionfortheforcebetweenthetwo��plateswhenthecapacitorhascharge,q.��Combinethefollowingequations:��d�VqF�Eq,E��,and�V��dCq����q2�VCF�Eq����q����q��ddCd2.Whatchargemustbestoredona22-�Fcapacitortohaveaforceof2.0Nbetweentheplatesiftheyareseparatedby1.5mm?q2F��Cdsoq��FCd����(2.0N�)(2.2��10�5F�)(1.5��10�3�m)�2.6�10�4CCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.444SolutionsManualPhysics:PrinciplesandProblems
448CHAPTER22CurrentElectricitypage598PracticeProblemsForallproblems,assumethatthebatteryvoltageand22.1CurrentandCircuitslampresistancesareconstant,nomatterwhatcurrentpages591–600ispresent.page5946.Anautomobilepanellampwitharesistance1.Thecurrentthroughalightbulbconnectedof33�isplacedacrossa12-Vbattery.acrosstheterminalsofa125-VoutletisWhatisthecurrentthroughthecircuit?0.50A.AtwhatratedoesthebulbconvertV12VI�����0.36Aelectricenergytolight?(Assume100percentR33�efficiency.)7.Amotorwithanoperatingresistanceof32�P�IV�(0.50A)(125V)�63J/s�63Wisconnectedtoavoltagesource.Thecurrentinthecircuitis3.8A.Whatisthevoltageof2.Acarbatterycausesacurrentof2.0Athesource?throughalampandproduces12Vacrossit.Whatisthepowerusedbythelamp?V�IR�(3.8A)(32�)�1.2�102VP�IV�(2.0A)(12V)�24W8.Asensoruses2.0�10�4Aofcurrentwhenitisoperatedbya3.0-Vbattery.Whatisthe3.Whatisthecurrentthrougha75-Wlight-resistanceofthesensorcircuit?bulbthatisconnectedtoa125-Voutlet?V3.0V4�P�IVR���I2.0���10�4A�1.5�10P75WI�����0.60AV125V9.Alampdrawsacurrentof0.50Awhenitisconnectedtoa120-Vsource.4.Thecurrentthroughthestartermotorofaa.Whatistheresistanceofthelamp?caris210A.Ifthebatterymaintains12Vacrossthemotor,howmuchelectricenergyR���V�120V�2.4�102�I0.50Aisdeliveredtothestarterin10.0s?b.WhatisthepowerconsumptionoftheP�IVandE�Ptlamp?Thus,E�IVt�(210A)(12V)(10.0s)1WP�IV�(0.50A)(120V)�6.0�10�2.5�104J10.A75-Wlampisconnectedto125V.5.Aflashlightbulbisratedat0.90W.Ifthea.Whatisthecurrentthroughthelamp?lightbulbdrops3.0V,howmuchcurrentP75Wgoesthroughit?I�����0.60AV125VP�IVb.Whatistheresistanceofthelamp?P0.90WI�����0.30AR���V�125V�2.1�102�V3.0VI0.60ACopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual445
449Chapter22continued11.Aresistorisaddedtothelampintheprevi-Aousproblemtoreducethecurrenttohalfof85mAitsoriginalvalue.�4.5V53�a.Whatisthepotentialdifferenceacross�thelamp?IThenewvalueofthecurrentisV4.5V0.60AR�����53���0.30AI0.085A2V�IR�(0.30A)(2.1�102�)14.Addavoltmetertomeasurethepotential�6.3�101Vdifferenceacrosstheresistorsinproblems12and13andrepeattheproblems.b.HowmuchresistancewasaddedtotheBothcircuitswilltakethefollowingform.circuit?ThetotalresistanceofthecircuitAisnow�R�V�125V2�Vtotal��I0.30A�4.2�10�ITherefore,Rres�Rtotal�RIampBecausetheammeterresistanceis�4.2�102��2.1�102�assumedzero,thevoltmeterreadings�2.1�102�willbe60.0VforPracticeProblem12and4.5VforPracticeProblem13.c.Howmuchpowerisnowdissipatedinthelamp?15.Drawacircuitusingabattery,alamp,aP�IV�(0.30A)(6.3�101V)�19Wpotentiometertoadjustthelamp’sbright-ness,andanon-offswitch.page600LampCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12.Drawacircuitdiagramtoincludea60.0-Vbattery,anammeter,andaresistanceof�12.5�inseries.Indicatetheammeterread-Battery�ingandthedirectionofthecurrent.SwitchPotentiometerA�4.80A16.Repeatthepreviousproblem,addingan60.0V12.5�ammeterandavoltmeteracrossthelamp.�IVV60.0VI�����4.80AR12.5��A�13.Drawaseries-circuitdiagramshowinga4.5-Vbattery,aresistor,andanammeterthatreads85mA.Determinetheresistanceandlabeltheresistor.Chooseadirectionfortheconventionalcurrentandindicatethepositiveterminalofthebattery.446SolutionsManualPhysics:PrinciplesandProblems
450Chapter22continuedP2/R2/12��12WSectionReview1�V1�(12V)P2/R2/9.0��16W22.1CurrentandCircuits2�V2�(12V)�P�Ppages591–6002�P1�16W�12W�4.0Wpage6004.0Wincrease17.SchematicDrawaschematicdiagramofacircuitthatcontainsabatteryandalight-21.EnergyAcircuitconverts2.2�103Jofbulb.Makesurethelightbulbwilllightinenergywhenitisoperatedfor3.0min.thiscircuit.Determinetheamountofenergyitwillconvertwhenitisoperatedfor1h.2.2�103JE�����(60.0min)3.0min��4.4�104J�22.CriticalThinkingWesaythatpoweris“dissipated”inaresistor.Todissipateistouse,towaste,ortosquander.Whatis“used”whenchargeflowsthrougharesistor?18.ResistanceJoestatesthatbecauseR�V/I,Thepotentialenergyofthechargesifheincreasesthevoltage,theresistancedecreasesastheyflowthroughtheresis-willincrease.IsJoecorrect?Explain.tor.ThisdecreaseinpotentialenergyisNo,resistancedependsonthedevice.usedtoproduceheatintheresistor.WhenVincreases,sowillI.19.ResistanceYouwanttomeasuretheresis-PracticeProblemstanceofalongpieceofwire.Showhowyou22.2UsingElectricEnergywouldconstructacircuitwithabattery,avoltmeter,anammeter,andthewiretobepages601–605testedtomakethemeasurement.Specifypage603whatyouwouldmeasureandhowyou23.A15-�electricheateroperatesona120-Vwouldcomputetheresistance.outlet.a.Whatisthecurrentthroughtheheater?AV120VI�����8.0AR15��b.HowmuchenergyisusedbytheheaterVin30.0s?�E�I2Rt�(8.0A)2(15�)(30.0s)�2.9�104JMeasurethecurrentthroughthewirec.Howmuchthermalenergyisliberatedandthepotentialdifferenceacrossit.inthistime?Dividethepotentialdifferencebythe2.9�104J,becauseallelectricenergycurrenttoobtainthewireresistance.isconvertedtothermalenergy.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.20.PowerAcircuithas12�ofresistanceand24.A39-�resistorisconnectedacrossa45-Visconnectedtoa12-Vbattery.Determinebattery.thechangeinpoweriftheresistancea.Whatisthecurrentinthecircuit?decreasesto9.0�.V45VI�����1.2AR39�Physics:PrinciplesandProblemsSolutionsManual447
451Chapter22continuedb.Howmuchenergyisusedbytheresistor27.A120-Vwaterheatertakes2.2htoheatain5.0min?givenvolumeofwatertoacertaintempera-2ture.Howlongwoulda240-VunitoperatingVE��twiththesamecurrenttaketoaccomplishR2thesametask?(45V)��(5.0min)(60s/min)(39�)tE�IVt�I(2V)���2�1.6�104JForagivenamountofenergy,doublingthevoltagewilldividethetimeby2.25.A100.0-Wlightbulbis22percentefficient.2.2hThismeansthat22percentoftheelectrict���1.1h2energyisconvertedtolightenergy.a.Howmanyjoulesdoesthelightbulbpage605convertintolighteachminuteitisin28.Anelectricspaceheaterdraws15.0Afromaoperation?120-Vsource.Itisoperated,ontheaverage,E�Ptfor5.0heachday.�(0.22)(100.0J/s)(1.0min)a.Howmuchpowerdoestheheateruse?(60s/min)P�IV�(15.0A)(120V)�1.3�103J�1800W�1.8kWb.Howmanyjoulesofthermalenergydoesb.HowmuchenergyinkWhdoesitcon-thelightbulbproduceeachminute?sumein30days?E�PtE�Pt�(1.8kW)(5.0h/day)(30days)�(0.78)(100.0J/s)(1.0min)�270kWh(60.0s/min)c.At$0.12perkWh,howmuchdoesit�4.7�103Jcosttooperatetheheaterfor30days?Cost�($0.12/kWh)(270kWh)26.TheresistanceofanelectricstoveelementatCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�$32.40operatingtemperatureis11�.a.If220Vareappliedacrossit,whatis29.Adigitalclockhasaresistanceof12,000�thecurrentthroughthestoveelement?andispluggedintoa115-Voutlet.I���V�220V�2.0�101Aa.Howmuchcurrentdoesitdraw?R11�I���V��115V�9.6�10�3Ab.HowmuchenergydoestheelementR12,000�converttothermalenergyin30.0s?b.Howmuchpowerdoesituse?E�I2Rt�(2.0�101A)2(11�)(30.0P�VI�(115V)(9.6�10�3A)�1.1Ws)c.Iftheowneroftheclockpays$0.12per�1.3�105JkWh,howmuchdoesitcosttooperatec.Theelementisusedtoheatakettlecon-theclockfor30days?taining1.20kgofwater.AssumethatCost�(1.1�10�3kWh)($0.12/kWh)65percentoftheheatisabsorbedby(30days)(24h/day)thewater.Whatisthewater’sincreaseintemperatureduringthe30.0s?�$0.10Q�mC�TwithQ�0.65E30.Anautomotivebatterycandeliver55Aat0.65E(0.65)(1.3�105J)12Vfor1.0handrequires1.3timesas�T������mC(1.20kg)(4180J/kg�°C)muchenergyforrechargeduetoitsless-�17°Cthan-perfectefficiency.Howlongwillit448SolutionsManualPhysics:PrinciplesandProblems
452Chapter22continuedtaketochargethebatteryusingacurrentofPV2/R(0.5V2/R��1���2��1)�0.257.5A?AssumethatthechargingvoltageisP2V2/RV211thesameasthedischargingvoltage.E35.EfficiencyEvaluatetheimpactofresearchcharge�(1.3)IVttoimprovepowertransmissionlineson�(1.3)(55A)(12V)(1.0h)societyandtheenvironment.�858WhResearchtoimprovepowertransmis-E858Wht������9.5hsionlineswouldbenefitsocietyincostIV(7.5A)(12V)ofelectricity.Also,iflesspowerwas31.Reworkthepreviousproblembyassuminglostduringtransmission,lesscoalandthatthebatteryrequirestheapplicationofotherpower-producingresourceswould14Vwhenitisrecharging.havetobeused,whichwouldimprovethequalityofourenvironment.Echarge�(1.3)IVt�(1.3)(55A)(12V)(1.0h)36.VoltageWhywouldanelectricrangeandanelectrichot-waterheaterbeconnectedto�858Wha240-Vcircuitratherthana120-Vcircuit?E858Wht������8.2hForthesamepower,attwicethevolt-IV(7.5A)(14V)age,thecurrentwouldbehalved.TheI2RlossinthecircuitwiringwouldbeSectionReviewdramaticallyreducedbecauseitispro-portionaltothesquareofthecurrent.22.2UsingElectricEnergypages601–60537.CriticalThinkingWhendemandforelec-page605tricpowerishigh,powercompaniessome-32.EnergyAcarenginedrivesagenerator,timesreducethevoltage,therebyproducingwhichproducesandstoreselectricchargeina“brown-out.”Whatisbeingsaved?thecar’sbattery.Theheadlampsusetheelec-Power,notenergy;mostdeviceswilltricchargestoredinthecarbattery.Listthehavetorunlonger.formsofenergyinthesethreeoperations.Mechanicalenergyfromtheenginecon-vertedtoelectricenergyinthegenera-ChapterAssessmenttor;electricenergystoredaschemicalConceptMappingenergyinthebattery;chemicalenergypage610convertedtoelectricenergyinthebat-38.Completetheconceptmapusingthefol-teryanddistributedtotheheadlamps;lowingterms:watt,current,resistance.electricenergyconvertedtolightandthermalenergyinheadlamps.Electricity33.ResistanceAhairdryeroperatingfrom120Vhastwosettings,hotandwarm.Inwhichsettingistheresistancelikelytoberateofrateofoppositionflowconversiontoflowsmaller?Why?Hotdrawsmorepower,P�IV,sotheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.fixedvoltagecurrentislarger.BecausecurrentpowerresistanceI�V/Rtheresistanceissmaller.34.PowerDeterminethepowerchangeinacircuitiftheappliedvoltageisdecreasedbyamperewattohmone-half.Physics:PrinciplesandProblemsSolutionsManual449
453Chapter22continuedMasteringConceptsb.Whichdeviceconvertschemicalenergytoelectricenergy?page61039.Definetheunitofelectriccurrentinterms1offundamentalMKSunits.(22.1)c.Whichdeviceturnsthecircuitonandoff?1A�1C/1s2d.Whichdeviceprovidesawaytoadjust40.Howshouldavoltmeterbeconnectedinspeed?Figure22-12tomeasurethemotor’s3voltage?(22.1)44.Describetheenergyconversionsthatoccurineachofthefollowingdevices.(22.1)4a.anincandescentlightbulbelectricenergytoheatandlight�3b.aclothesdryer1�electricenergytoheatandkineticenergyc.adigitalclockradio2electricenergytolightandsound■Figure22-1245.WhichwireconductselectricitywithThepositivevoltmeterleadconnectstheleastresistance:onewithalargetotheleft-handmotorlead,andthecross-sectionaldiameteroronewithanegativevoltmeterleadconnectstosmallcross-sectionaldiameter?(22.1)theright-handmotorlead.Alarger-diameterwirehasasmallerresistancebecausetherearemore41.Howshouldanammeterbeconnectedinelectronstocarrythecharge.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Figure22-12tomeasurethemotor’scur-rent?(22.1)46.Asimplecircuitconsistsofaresistor,aBreakthecircuitbetweenthebatterybattery,andconnectingwires.(22.1)andthemotor.Thenconnecttheposi-a.Drawacircuitschematicofthissimpletiveammeterleadtothepositivesideofcircuit.thebreak(thesideconnectedtothepositivebatteryterminal)andthenega-tiveammeterleadtothenegativesideIInearestthemotor.��42.WhatisthedirectionoftheconventionalmotorcurrentinFigure22-12?(22.1)b.Howmustanammeterbeconnectedinfromlefttorightthroughthemotoracircuitforthecurrenttobecorrectlyread?43.RefertoFigure22-12toanswerthefollow-Theammetermustbeconnectediningquestions.(22.1)series.a.Whichdeviceconvertselectricenergytomechanicalenergy?4450SolutionsManualPhysics:PrinciplesandProblems
454Chapter22continuedVApplyingConceptspages610–61151.BatteriesWhenabatteryisconnectedtoaIIAcompletecircuit,chargesflowinthecircuit��almostinstantaneously.Explain.Apotentialdifferenceisfeltovertheentirecircuitassoonasthebatteryisc.Howmustavoltmeterbeconnectedtoconnectedtothecircuit.Thepotentialaresistorforthepotentialdifferencedifferencecausesthechargestobeginacrossittoberead?toflow.Note:ThechargesflowslowlyThevoltmetermustbeconnectedincomparedtothechangeinpotentialparallel.difference.V52.Explainwhyacowexperiencesamildshockwhenittouchesanelectricfence.IIABytouchingthefenceandtheground,thecowencountersadifferencein��potentialandconductscurrent,thusreceivingashock.47.Whydolightbulbsburnoutmorefrequentlyjustastheyareswitchedonratherthan53.PowerLinesWhycanbirdsperchonhigh-whiletheyareoperating?(22.2)voltagelineswithoutbeinginjured?ThelowresistanceofthecoldfilamentNopotentialdifferenceexistsalongtheallowsahighcurrentinitiallyandawires,sothereisnocurrentthroughgreaterchangeintemperature,subject-thebirds’bodies.ingthefilamenttogreaterstress.54.Describetwowaystoincreasethecurrentin48.Ifabatteryisshort-circuitedbyaheavycop-acircuit.perwirebeingconnectedfromoneterminalEitherincreasethevoltageordecreasetotheother,thetemperatureofthecoppertheresistance.wirerises.Whydoesthishappen?(22.2)Theshortcircuitproducesahighcur-55.LightbulbsTwolightbulbsworkonarent,whichcausesmoreelectronsto120-Vcircuit.Oneis50Wandtheotheriscollidewiththeatomsofthewire.This100W.Whichbulbhasahigherresistance?raisestheatoms’kineticenergiesandExplain.thetemperatureofthewire.50-WbulbV2V249.WhatelectricquantitiesmustbekeptsmallP��,soR��RPtotransmitelectricenergyeconomicallyTherefore,thelowerPiscausedbyaoverlongdistances?(22.2)higherR.theresistanceofthewireandthecurrentinthewire56.Ifthevoltageacrossacircuitiskeptcon-stantandtheresistanceisdoubled,whatCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.50.Definetheunitofpowerintermsoffunda-effectdoesthishaveonthecircuit’scurrent?mentalMKSunits.(22.2)Iftheresistanceisdoubled,thecurrentm2Jkg���2kg�m2ishalved.CJsW������������sCsss3Physics:PrinciplesandProblemsSolutionsManual451
455Chapter22continued57.WhatistheeffectonthecurrentinacircuitMotorifboththevoltageandtheresistanceare1.5Adoubled?Explain.Noeffect.V�IR,soI�V/R,andifthe��voltageandtheresistancebotharedoubled,thecurrentwillnotchange.12V58.Ohm’sLawSuefindsadevicethatlookslikearesistor.Whensheconnectsittoa■Figure22-131.5-Vbattery,shemeasuresonly45�10�6A,a.Howmuchpowerisdeliveredtothebutwhensheusesa3.0-Vbattery,shemea-motor?sures25�10�3A.DoesthedeviceobeyP�VI�(12V)(1.5A)�18WOhm’slaw?b.HowmuchenergyisconvertediftheNo.V�IR,soR�V/I.At1.5V,motorrunsfor15min?1.5V4�R����45�10�63.3�10E�Pt�(18W)(15min)(60s/min)3.0V�1.6�104JAt3.0V,R����25�10�3A120�AdevicethatobeysOhm’slawhasa62.RefertoFigure22-14toanswerthefollow-resistancethatisindependentoftheingquestions.appliedvoltage.A59.IftheammeterinFigure22-4aonpage596weremovedtothebottomofthediagram,�wouldtheammeterhavethesamereading?27V18�VExplain.�Yes,becausethecurrentisthesameeverywhereinthiscircuit.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.I60.Twowirescanbeplacedacrossthetermi-nalsofa6.0-Vbattery.Onehasahighresis-■Figure22-14tance,andtheotherhasalowresistance.a.Whatshouldtheammeterreadingbe?Whichwirewillproducethermalenergyat27Vafasterrate?Why?I�V/R���1.5A18�thewirewiththesmallerresistanceb.Whatshouldthevoltmeterreadingbe?V227VP��Rc.HowmuchpowerisdeliveredtotheSmallerRproduceslargerpowerPresistor?dissipatedinthewire,whichproducesP�VI�(27V)(1.5A)�41Wthermalenergyatafasterrate.d.HowmuchenergyisdeliveredtotheMasteringProblemsresistorperhour?22.1CurrentandCircuitsE�Pt�(41W)(3600s)�1.5�105Jpages611–612Level161.Amotorisconnectedtoa12-Vbattery,asshowninFigure22-13.452SolutionsManualPhysics:PrinciplesandProblems
456Chapter22continued63.RefertoFigure22-15toanswerthefollow-d.Howmuchenergyisdeliveredtotheingquestions.resistorperhour?E�Pt�(4.5W)(3600s)�1.6�104JA65.ToastersThecurrentthroughatoasterthatisconnectedtoa120-Vsourceis8.0A.�27V9.0�VWhatpowerisdissipatedbythetoaster?�2WP�IV�(8.0A)(120V)�9.6�1066.LightbulbsAcurrentof1.2AismeasuredIthroughalightbulbwhenitisconnectedacrossa120-Vsource.Whatpowerisdissi-■Figure22-15patedbythebulb?a.Whatshouldtheammeterreadingbe?P�IV�(1.2A)(120V)�1.4�102W27VI�V/R���3.0A9.0�67.Alampdraws0.50Afroma120-Vgenerator.b.Whatshouldthevoltmeterreadingbe?a.Howmuchpowerisdelivered?27VP�IV�(0.50A)(120V)�6.0�101Wc.Howmuchpowerisdeliveredtotheresistor?b.Howmuchenergyisconvertedin5.0min?P�VI�(27V)(3.0A)�81WEd.HowmuchenergyisdeliveredtotheThedefinitionofpowerisP���,sotresistorperhour?E�PtE�Pt�(81W)(3600s)�2.9�105J1W)5.0min60s�(6.0�10������1min64.RefertoFigure22-16toanswerthefollow-4J�18,000J�1.8�10ingquestions.68.A12-VautomobilebatteryisconnectedtoAanelectricstartermotor.Thecurrentthroughthemotoris210A.�a.Howmanyjoulesofenergydoesthe9.0V18�Vbatterydelivertothemotoreachsecond?�P�IV�(210A)(12V)�2500J/sor2.5�103J/sIb.Whatpower,inwatts,doesthemotoruse?■Figure22-163WP�2.5�10a.Whatshouldtheammeterreadingbe?9.0V69.DryersA4200-Wclothesdryerisconnect-I�V/R���0.50A18�edtoa220-Vcircuit.Howmuchcurrentb.Whatshouldthevoltmeterreadingbe?doesthedryerdraw?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.9.0VP�IVc.HowmuchpowerisdeliveredtotheP4200WI�������19Aresistor?V220VP�VI�(9.0V)(0.50A)�4.5WPhysics:PrinciplesandProblemsSolutionsManual453
457Chapter22continued70.FlashlightsAflashlightbulbisconnectedTable22-2acrossa3.0-Vpotentialdifference.Thecur-Voltage,VCurrent,IResistance,R�V/Irentthroughthebulbis1.5A.(volts)(amps)(amps)a.Whatisthepowerratingofthebulb?2.000.0140______________P�IV�(1.5A)(3.0V)�4.5W4.000.0270______________b.Howmuchelectricenergydoesthebulb6.000.0400______________convertin11min?8.000.0520______________EThedefinitionofpowerisP���,so10.000.0630______________t�2.00�0.0140______________E�Pt�4.00�0.0280______________60s�(4.5W)(11min)��m�in��6.00�0.0390______________�8.00�0.0510______________�3.0�103J�10.00�0.0620______________71.BatteriesAresistorof60.0�hasacurrenta.Foreachmeasurement,calculatetheof0.40Athroughitwhenitisconnectedtoresistance.theterminalsofabattery.Whatisthevolt-R�143�,R�148�,R�150�,ageofthebattery?R�154�,R�159�,R�143�,V�IR�(0.40A)(60.0�)�24VR�143�,R�154�,R�157�,R�161�72.Whatvoltageisappliedtoa4.0-�resistorifthecurrentis1.5A?b.GraphIversusV.V�IR�(1.5A)(4.0�)�6.0V0.0673.Whatvoltageisplacedacrossamotorwith0.04a15-�operatingresistanceifthereis8.0Aofcurrent?0.02Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.V�IR�(8.0A)(15�)�1.2�102V�12.00�8.00�4.000.004.008.0012.0074.Avoltageof75Visplacedacrossa15-�I(amps)resistor.Whatisthecurrentthroughtheresistor?�0.04V�IRV75V�0.06I������5.0AR15�V(volts)Level2c.DoesthenichromewireobeyOhm’s75.Somestudentsconnectedalengthoflaw?Ifnot,forallthevoltages,specifythenichromewiretoavariablepowersupplyvoltagerangeforwhichOhm’slawholds.toproducebetween0.00Vand10.00Vacrossthewire.TheythenmeasuredtheOhm’slawisobeyedwhenthecurrentthroughthewireforseveralvolt-resistanceofadeviceisconstantages.Thestudentsrecordedthedatafortheandindependentofthepotentialvoltagesusedandthecurrentsmeasured,asdifference.TheresistanceoftheshowninTable22-2.nichromewireincreasessomewhatasthemagnitudeofthevoltageincreases,sothewiredoesnotquiteobeyOhm’slaw.454SolutionsManualPhysics:PrinciplesandProblems
458Chapter22continued76.Drawaseriescircuitdiagramtoincludea79.Thecurrentthroughalampconnected16-�resistor,abattery,andanammeteracross120Vis0.40Awhenthelampison.thatreads1.75A.Indicatethepositiveter-a.Whatisthelamp’sresistancewhenitminalandthevoltageofthebattery,theison?positiveterminaloftheammeter,andtheV�IRdirectionofconventionalcurrent.V120V2�R������3.0�10�I0.40AAb.Whenthelampiscold,itsresistanceisI�1.75A�1��asgreatasitiswhenthelampishot.V�28V16�5�Whatisthelamp’scoldresistance?I��1��(3.0�102�)�6.0�101�5V�IR�(1.75A)(16�)�28Vc.Whatisthecurrentthroughthelampas77.Alampdrawsa66-mAcurrentwhencon-itisturnedonifitisconnectedtoanectedtoa6.0-Vbattery.Whena9.0-Vpotentialdifferenceof120V?batteryisused,thelampdraws75mA.V�IRa.DoesthelampobeyOhm’slaw?V120VI������2.0AR6.0�101�No.Thevoltageisincreasedbya9.0factorof���1.5,butthecurrentLevel36.075isincreasedbyafactorof���1.180.ThegraphinFigure22-17showsthecur-66rentthroughadevicecalledasilicondiode.b.Howmuchpowerdoesthelampdissi-patewhenitisconnectedtothe6.0-VCurrentinaDiodebattery?P�IV�(66�10�3A)(6.0V)�0.40Wc.Howmuchpowerdoesitdissipateat0.029.0V?P�IV�(75�10�3A)(9.0V)�0.68WCurrent(A)0.0178.LightbulbsHowmuchenergydoesa60.0-Wlightbulbuseinhalfanhour?Ifthelight-00.20.40.60.8bulbconverts12percentofelectricenergytoVoltage(V)lightenergy,howmuchthermalenergydoes■Figure22-17itgenerateduringthehalfhour?a.Apotentialdifferenceof�0.70VisEP���placedacrossthediode.Whatisthetresistanceofthediode?E�Pt�(60.0W)(1800s)Fromthegraph,I�22m/A,and�1.08�105JV�IR,soIfthebulbis12percentefficient,V0.70VR�������32�88percentoftheenergyislosttoheat,soI2.2�10�2ACopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Q�(0.88)(1.08�105J)�9.5�104Jb.Whatisthediode’sresistancewhena�0.60-Vpotentialdifferenceisused?V0.60V2�R�������1.2�10I5.2�10�3Ac.DoesthediodeobeyOhm’slaw?No.Resistancedependsonvoltage.Physics:PrinciplesandProblemsSolutionsManual455
459Chapter22continued81.Drawaschematicdiagramtoshowacircuitincludinga90-Vbattery,anammeter,andaresistanceof45�connectedinseries.Whatistheammeterreading?Drawarrowsshow-�ingthedirectionofconventionalcurrent.V40.0��A2A�90V45�I�I■Figure22-18a.themaximumsafecurrentV�IRP�I2RV90VI������2A1WR45�P5.0�10I����������1AR40.0�b.themaximumsafevoltage22.2UsingElectricEnergyP�V2/Rpages612–613Level1V��PR���(5.0���101W)(40.0���)82.BatteriesA9.0-Vbatterycosts$3.00and�45Vwilldeliver0.0250Afor26.0hbeforeitmustbereplaced.CalculatethecostperkWh.86.UtilitiesFigure22-19representsanelec-E�IVt�(0.0250A)(9.0V)(26.0h)tricfurnace.Calculatethemonthly(30-day)�5.9Wh�5.9�10�3kWhheatingbillifelectricitycosts$0.10perkWhandthethermostatisonone-fourthofcost$3.00Rate������E5.9�10�3kWhthetime.�$510/kWhThermostatCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.83.Whatisthemaximumcurrentallowedina5.0-W,220-�resistor?�P�I2R240.0V4.80��P5.0WI����������0.15AR220�84.A110-Velectricirondraws3.0Aofcurrent.Howmuchthermalenergyisdevelopedin■Figure22-19anhour?V2Q�E�VIt�(110V)(3.0A)(1.0h)(3600s/h)E���R��(t)�1.2�106J(240.0V)2���4.80���(30d)(24h/d)(0.25)�2160kWhLevel285.ForthecircuitshowninFigure22-18,theCost�(2160kWh)($0.100/kWh)�$216maximumsafepoweris5.0�101W.Usethefiguretofindthefollowing:87.AppliancesAwindowairconditionerisesti-matedtohaveacostofoperationof$50per30days.Thisisbasedontheassumptionthattheairconditionerwillrunhalfofthetime456SolutionsManualPhysics:PrinciplesandProblems
460Chapter22continuedandthatelectricitycosts$0.090perkWh.90.Acurrentof1.2AismeasuredthroughaDeterminehowmuchcurrenttheaircondi-50.0-�resistorfor5.0min.Howmuchheattionerwilltakefroma120-Voutlet.isgeneratedbytheresistor?Cost�(E)(rate)Q�E�I2RtE�Co�st��$5�02(50.0�)(5.0min)�60�s��(1.2A)��rate$0.090/kWhmin�556kWh�2.2�104JE�IVt91.A6.0-�resistorisconnectedtoa15-VE(556kWh)(1000W/kW)battery.I�������Vt(120V)(30d)(24h/d)(0.5)a.Whatisthecurrentinthecircuit?�12.9AV�IRV15V88.RadiosAtransistorradiooperatesbyI�������2.5AR6.0�meansofa9.0-Vbatterythatsuppliesitb.Howmuchthermalenergyisproducedwitha50.0-mAcurrent.in10.0min?a.Ifthecostofthebatteryis$2.49andit2RtQ�E�Ilastsfor300.0h,whatisthecostperkWhtooperatetheradiointhismanner?�(2.5A)2(6.0�)(10.0min)��60�s�minP�IV�(0.050A)(9.0V)�0.45W4J�2.3�10�4.5�10�4kW$2.49Level2Cost����(4.5�10�4kW)(300.0h)92.LightbulbsAnincandescentlightbulbwith�$18.00/kWharesistanceof10.0�whenitisnotlitandaresistanceof40.0�whenitislithasb.Thesameradio,bymeansofaconverter,120Vplacedacrossit.ispluggedintoahouseholdcircuitbyahomeownerwhopays$0.12perkWh.a.WhatisthecurrentdrawwhenthebulbWhatdoesitnowcosttooperatetheislit?radiofor300.0h?V120VI�������3.0AR40.0�Cost�($0.12/kWh)(4.5�10�4kW)(300h)b.Whatisthecurrentdrawattheinstantthebulbisturnedon?�$0.02V120VI�������12AR10.0�MixedReviewc.Whendoesthelightbulbusethemostpage613power?Level1theinstantitisturnedon89.Ifapersonhas$5,howlongcouldheorsheplaya200Wstereoifelectricitycosts93.A12-Velectricmotor’sspeediscontrolled$0.15perkWh?byapotentiometer.Atthemotor’sslowestCostsetting,ituses0.02A.Atitshighestsetting,E�Pt���Ratethemotoruses1.2A.WhatistherangeofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Costthepotentiometer?t���(Rate)(P)Theslowestspeed’sresistanceis$5R�V/I�12V/0.02A�600�.The����($0.15/kWh)(200W)��1k�W�fastestspeed’sresistanceis1000WR�V/I�12V/1.2A�1.0�101�.�200hTherangeis1.0�101�to600�.Physics:PrinciplesandProblemsSolutionsManual457
461Chapter22continuedLevel3Q�T���94.Anelectricmotoroperatesapumpthatirri-mCgatesafarmer’scropbypumping1.0�104L1.1�106J����ofwateraverticaldistanceof8.0mintoa(20.0kg)(4180J/kg�C°)fieldeachhour.Themotorhasanoperating�13°Cresistanceof22.0�andisconnectedacrossd.At$0.08perkWh,howmuchdoesita110-Vsource.costtooperatetheheatingcoil30mina.Whatcurrentdoesthemotordraw?perdayfor30days?V�IR1.1�106J30minCost��������(30days)V110V5mindayI�����5.0AR22.0�1kWh$0.08b.Howefficientisthemotor?����3.6�106J��kWh�EW�mgd�$4.40�(1�104kg)(9.80m/s2)(8.0m)96.AppliancesAnelectricheaterisratedat�8�105J500W.Ea.Howmuchenergyisdeliveredtothem�IVt�(5.0A)(110V)(3600s)heaterinhalfanhour?�2.0�106JE�Pt�(5�102W)(1800s)EEfficiency���w100E�9�105Jm8�105Jb.Theheaterisbeingusedtoheataroom���2.0�106J�100containing50kgofair.Ifthespecificheatofairis1.10kJ/kg�°C,and50per-�40%centofthethermalenergyheatstheair95.Aheatingcoilhasaresistanceof4.0�andintheroom,whatisthechangeinairoperateson120V.temperatureinhalfanhour?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.WhatisthecurrentinthecoilwhileitisQ�mC�Toperating?Q�T���mCV�IR(0.5)(9�105J)I�V����120V3.0�101A�����(50.0kg)(1100J/kg�C°)R4.0�b.Whatenergyissuppliedtothecoilin�8°C5.0min?c.At$0.08perkWh,howmuchdoesit2Rtcosttoruntheheater6.0hperdayforE�I30days?�(3.0�101A)2(4.0�)(5.0min)��60�s�min500J6.0h3600sCost����������sdayh�1.1�106J1kWH$0.08c.Ifthecoilisimmersedinaninsulated(30days)����6J��kWh�3.6�10containerholding20.0kgofwater,�$7whatwillbetheincreaseinthetemper-atureofthewater?Assume100percentThinkingCriticallyoftheheatisabsorbedbythewater.page614Q�mC�T97.FormulateModelsHowmuchenergyisstoredinacapacitor?Theenergyneededtoincreasethepotentialdifferenceofacharge,q,458SolutionsManualPhysics:PrinciplesandProblems
462Chapter22continuedisrepresentedbyE�qV.Butinacapacitor,Figure22-2bonpage593.LabeltheV�q/C.Thus,aschargeisadded,thepoten-functionofeachblockaccordingtotialdifferenceincreases.Asmorechargeistotaljoulespersecond.added,however,ittakesmoreenergytoaddtheadditionalcharge.Considera1.0-FMicrowaveHeatUsefulInput→→→converterconverteroutput“supercap”usedasanenergystoragedevice1440J/s1440J/s1080J/s810J/sinapersonalcomputer.PlotagraphofVas→→thecapacitorischargedbyadding5.0Ctoit.Whatisthevoltageacrossthecapacitor?TheWastedWastedareaunderthecurveistheenergystoredin360J/s270J/sthecapacitor.Findtheenergyinjoules.Isitequaltothetotalchargetimesthefinalb.Deriveanequationfortherateoftem-potentialdifference?Explain.peratureincrease(T/s)fromtheinfor-mationpresentedinChapter12.Solve5.0fortherateoftemperaturerisegiventherateofenergyinput,themass,andthe4.0specificheatofasubstance.3.0�T1�Q����������tmC�t2.0c.Useyourequationtosolvefortherate1.0oftemperatureriseindegreesCelsiusPotentialdifference(V)persecondwhenusingthisoventoheat0.01.02.03.04.05.0250gofwateraboveroomtemperature.Charge(C)�T1�Q����������tmC�tq5.0CVoltageV������5.0VC1.0F810J/s����(0.25kg)(4180J/kg�°C)EnergyE�areaundercurve�0.78°C/s1��2(5.0V)(5.0C)d.Reviewyourcalculationscarefullyfortheunitsusedanddiscusswhyyour�13Janswerisinthecorrectform.No.Graphically,totalchangetimesfinalThekgunitcancelsandtheJunitpotentialdifferenceisexactlytwicethecancels,leaving°C/s.areaunderthecurve.Physically,ite.Discuss,ingeneralterms,differentwaysmeansthateachcoulombwouldrequireinwhichyoucouldincreasetheefficiencythesamemaximumamountofenergyofmicrowaveheating.toplaceitonthecapacitor.Actually,theTheefficiencyofconversionfromamountofenergyneededtoaddeachelectricenergytomicrowaveenergyischargeincreasesaschargeaccumu-75percent.Itmightbepossibletofindlatesonthecapacitor.awaytoconvertelectricenergytoradiationusingadifferentapproach98.ApplyConceptsAmicrowaveovenoper-thatwouldbemoreefficient.Theeffi-atesat120Vandrequires12Aofcurrent.ciencyofconversionfrommicrowaveCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Itselectricefficiency(convertingACtoradiationtothermalenergyinwaterismicrowaveradiation)is75percent,andits75percent.Itmightbepossibletouseconversionefficiencyfrommicrowaveradia-adifferentfrequencyofelectromag-tiontoheatingwaterisalso75percent.neticradiationtoimprovethisrating.a.DrawablockpowerdiagramsimilarOr,itmightbepossibletofindanewtotheenergydiagramshowninPhysics:PrinciplesandProblemsSolutionsManual459
463Chapter22continuedgeometryofradiatingobjectstobe100.ApplyConceptsThesizesof10-�resis-heatedtoimprovetheefficiency.torsrangefromapinheadtoasoupcan.f.Discuss,inefficiencyterms,whyExplain.microwaveovensarenotusefulforheat-Thephysicalsizeofaresistorisdeter-ingeverything.minedbyitspowerrating.ResistorsTheconversionefficiencyfromratedat100Waremuchlargerthanmicrowaveenergytothermalenergythoseratedat1W.isgoodforwater.It’snotasgoodforothermaterials.Thecontainers101.MakeandUseGraphsThediodegraphanddishesdesignedforusewithshowninFigure22-17onpage612ismicrowaveovensconvertlittleofthemoreusefulthanasimilargraphforaenergy.resistorthatobeysOhm’slaw.Explain.g.Discuss,ingeneralterms,whyitisnotThevolt–amperegraphforaresistoragoodideatorunmicrowaveovensobeyingOhm’slawisastraightlinewhentheyareempty.andisseldomnecessary.Theemptyovenmeansthatthe102.MakeandUseGraphsBasedonwhatmicrowaveenergyhastobedissi-youhavelearnedinthischapter,identifypatedintheoven.Thiscanleadtoandpreparetwoparabolicgraphs.overheatingoftheovencompo-voltage–powerandcurrent–powernentsandtotheirfailure.P�I2R99.AnalyzeandConcludeAsalesclerkinan40appliancestorestatesthatmicrowaveovensarethemostelectricallyefficient30meansofheatingobjects.a.Formulateanargumenttorefutethe20clerk’sclaim.Hint:Thinkaboutheatingaspecificobject.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Wattsdissipated10Inthecaseofheatingacupofwater,animmersionheaterusesonlyresistanceforenergyconver-05101520sionandisnearly100percenteffi-Voltageacrossa10-�resistorcient.Amicrowaveovenusestwoenergyconversions(electricitytoV2microwaveradiationtoheat)andisP�Rtypicallyaround50percentefficient.40b.Formulateanargumenttosupporttheclerk’sclaim.Hint:Thinkaboutheating30aspecificobject.Inthecaseofheatingapotato,a20microwaveovenheatsmostlythepotatoandismoreefficientthananWattsdissipatedelectricovenorskillet,whichalso10heatstheair,cabinets,racks,etc.c.Formulateadiplomaticreplytothe012clerk.Amperesthrougha10-�resistor“Itcanbetrue,butitdependsonthespecificapplication.”460SolutionsManualPhysics:PrinciplesandProblems
464Chapter22continuedWritinginPhysics�S�(20kg)(3.34�105J/kg)/(273K)page614�2.4�104J/K103.Therearethreekindsofequationsencoun-teredinscience:(1)definitions,(2)laws,106.Whenyougouptheelevatorofatalland(3)derivations.Examplesoftheseare:building,yourearsmightpopbecauseof(1)anampereisequaltoonecoulombtherapidchangeinpressure.Whatisthepersecond,(2)forceisequaltomasspressurechangecausedbyridinginanele-timesacceleration,(3)powerisequaltovatorupa30-storybuilding(150m)?Thevoltagesquareddividedbyresistance.densityofairisabout1.3kg/m3atseaWriteaone-pageexplanationofwherelevel.(Chapter13)“resistanceisequaltovoltagedividedby�P��ghcurrent”fits.Beforeyoubegintowrite,�(1.3kg/m3)(9.80m/s2)(150m)firstresearchthethreecategoriesgivenabove.�1.9kPaorabout2/100ofThestudent’sanswershouldincludethetotalairpressuretheidea(1)that,fordevicesobeyingOhm’slaw,thevoltagedropispropor-107.Whatisthewavelengthinairofa17-kHztionaltocurrentthroughthedevicesoundwave,whichisattheupperendofand(2)thattheformulaR�V/I,thethefrequencyrangeofhumanhearing?definitionofresistance,isaderivation(Chapter15)fromOhm’slaw.v��fv343m/s104.InChapter13,youlearnedthatmatter�������0.020m�2.0cmf17,000Hzexpandswhenitisheated.Researchtherelationshipbetweenthermalexpansion108.Lightofwavelength478nmfallsonaandhigh-voltagetransmissionlines.doubleslit.First-orderbrightbandsappearAnswerswillvary,butstudentsshould3.00mmfromthecentralbrightband.determinethattransmissionlinescanThescreenis0.91mfromtheslits.Howbecomehotenoughtoexpandandsagfarapartaretheslits?(Chapter19)whentheyhavehighcurrents.Saggingxd����linescanbedangerousiftheytouchLobjectsbeneaththem,suchastreesor�Ld���otherpowerlines.x(478�10�9m)(0.91m)����CumulativeReview(3.00�10�3m)page614�1.4�10�4m105.Apersonburnsenergyattherateofabout8.4�106Jperday.Howmuchdoesshe109.Achargeof�3.0�10�6Cis2.0mfromaincreasetheentropyoftheuniverseinsecondchargeof�6.0�10�5C.Whatisthatday?Howdoesthiscomparetothethemagnitudeoftheforcebetweenthem?entropyincreasecausedbymelting20kg(Chapter20)ofice?(Chapter12)qF�K�AqB�S�Q/TwhereTisthebody2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.dtemperatureof310K.�(9.0�109N�m2/C2)�S�(8.4�106J)/(310K)(3.0�10�6C)(6.0�10�5C)�2.7�104J/K����2(2.0m)Formeltingice�0.41NPhysics:PrinciplesandProblemsSolutionsManual461
465Chapter22continuedChallengeProblemSwitch2page604Switch1Usethefiguretotherighttohelpyouanswerthe1.5�Fquestionsbelow.15V1.Initially,thecapacitorisuncharged.Switch11200�isclosed,andSwitch2remainsopen.Whatisthevoltageacrossthecapacitor?15V2.Switch1isnowopened,andSwitch2remainsopen.Whatisthevoltageacrossthecapacitor?Why?Itremains15Vbecausethereisnopathforthechargetoberemoved.3.Next,Switch2isclosed,whileSwitch1remainsopen.Whatisthevoltageacrossthecapacitorandthecurrentthroughtheresis-torimmediatelyafterSwitch2isclosed?15Vand13mA4.Astimegoeson,whathappenstothevolt-ageacrossthecapacitorandthecurrentthroughtheresistor?Thecapacitorvoltageremainsat15Vbecausethereisnopathtodischargethecapacitor;thecurrentremainsatCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.13mAbecausethebatteryvoltageisconstantat15V.However,ifthebat-teryandcapacitorwererealcompo-nentsinsteadofidealcircuitcompo-nents,thecapacitorvoltageeventuallywouldbecomezeroduetoleakage,andthecurrenteventuallywouldbecomezeroduetobatterydepletion.462SolutionsManualPhysics:PrinciplesandProblems
466CHAPTER23SeriesandParallelCircuitsa.WhatistheequivalentresistanceofthePracticeProblemscircuit?23.1SimpleCircuitsV120V3�R�����2�10pages617–626I0.06Apage619b.Whatistheresistanceofeachbulb?1.Three20-�resistorsareconnectedinseriesR2�103�2�R���acrossa120-Vgenerator.Whatistheequiv-bulb�10�10�2�10alentresistanceofthecircuit?Whatisthe5.Calculatethevoltagedropsacrossthethreecurrentinthecircuit?resistorsinproblem2,andverifythattheirR�R1�R2�R3sumequalsthevoltageofthebattery.�20��20��20�V1�IR1�(3A)(10�)�30V�60�V2�IR2�(3A)(15�)�45VV120VV3�IR3�(3A)(5�)�15VI�����2AR60�V1�V2�V3�30V�45V�15V2.A10-�,15-�,and5-�resistorareconnect-�90Vedinaseriescircuitwitha90-Vbattery.�voltageofbatteryWhatistheequivalentresistanceofthecir-cuit?Whatisthecurrentinthecircuit?page622R�R1�R2�R36.ThecircuitshowninExampleProblem1is�10��15��5��30�producingthesesymptoms:theammeterreads0A,VV90VAreads0V,andVBreads45V.I�����3AWhathashappened?R30�R3.A9-Vbatteryisinacircuitwiththreeresis-Bhasfailed.Ithasinfiniteresistance,andthebatteryvoltageappearsacrosstorsconnectedinseries.it.a.Iftheresistanceofoneoftheresistorsincreases,howwilltheequivalentresis-7.SupposethecircuitshowninExampletancechange?Problem1hasthesevalues:RA�255�,Itwillincrease.RB�292�,andVA�17.0V.Nootherb.Whatwillhappentothecurrent?informationisavailable.Va.Whatisthecurrentinthecircuit?I��,soitwilldecrease.RV17.0VI�����66.7mAc.WilltherebeanychangeinthebatteryR255.0�voltage?b.Whatisthebatteryvoltage?No.ItdoesnotdependontheFirst,findthetotalresistance,thenresistance.solveforvoltage.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.R�RA�RB4.Astringofholidaylightshastenbulbswithequalresistancesconnectedinseries.When�255��292�thestringoflightsisconnectedtoa120-V�547�outlet,thecurrentthroughthebulbsisV�IR�(66.7mA)(547�)�36.5V0.06A.Physics:PrinciplesandProblemsSolutionsManual463
467Chapter23continuedc.WhatarethetotalpowerdissipationVsource�VA�VB�VCandtheindividualpowerdissipations?VC�Vsource�(VA�VB)P�IV�(66.7mA)(36.5V)�2.43W�12.0V�(1.21V�3.33V)�7.46VP2RA�IA�(66.7mA)2(255�)page623�1.13W11.A22-�resistoranda33-�resistorarecon-P2Rnectedinseriesandplacedacrossa120-VB�IB�(66.7mA)2(292�)potentialdifference.a.Whatistheequivalentresistanceofthe�1.30Wcircuit?d.DoesthesumoftheindividualpowerR�Rdissipationsinthecircuitequalthetotal1�R2�22��33��55�powerdissipationinthecircuit?Explain.b.Whatisthecurrentinthecircuit?Yes.Thelawofconservationofener-V120VI�����2.2Agystatesthatenergycannotbecre-R55�atedordestroyed;therefore,theratec.Whatisthevoltagedropacrosseachatwhichenergyisconverted,orresistor?powerdissipated,willequalthesumV1�IR1ofallparts.V����RR18.Holidaylightsoftenareconnectedinseriesandusespeciallampsthatshortoutwhen120V����(22�)55�thevoltageacrossalampincreasestothelinevoltage.Explainwhy.Alsoexplainwhy�48Vtheselightsetsmightblowtheirfusesafter120VV�manybulbshavefailed.2�IR2���55�(33�)�72VIfnotfortheshortingmechanism,thed.WhatisthevoltagedropacrossthetwoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.entiresetwouldgooutwhenonelampresistorstogether?burnsout.AfterseverallampsfailandV�48V�72V�1.20�102Vthenshort,thetotalresistanceoftheremainingworkinglampsresultsinan12.Threeresistorsof3.3k�,4.7k�,and3.9increasedcurrentthatissufficienttok�areconnectedinseriesacrossa12-Vblowthefuse.battery.a.Whatistheequivalentresistance?9.ThecircuitinExampleProblem1hasunequalresistors.ExplainwhytheresistorR�3.3k��4.7k��3.9k�withthelowerresistancewilloperateata�1.2�101k�lowertemperature.b.Whatisthecurrentthroughtheresistors?TheresistorwiththelowerresistanceV12VI�����willdissipatelesspower,andthuswillR12�104�becooler.�1.0mA�1.0�10�3A10.Aseriescircuitismadeupofa12.0-Vbat-c.Whatisthevoltagedropacrosseachteryandthreeresistors.Thevoltageacrossresistor?oneresistoris1.21V,andthevoltageacrossV�IRanotherresistoris3.33V.Whatisthevolt-V�3A)�3.3Vageacrossthethirdresistor?1�(3.3k�)(1.0�10V�3A)�4.7V2�(4.7k�)(1.0�10464SolutionsManualPhysics:PrinciplesandProblems
468Chapter23continuedV�3A)�3.9V16.A120.0-�resistor,a60.0-�resistor,anda3�(3.9k�)(1.0�1040.0-�resistorareconnectedinparallelsoV�3.3V,4.7V,and3.9Vandplacedacrossa12.0-Vbattery.d.Findthetotalvoltagedropacrossthea.Whatistheequivalentresistanceofthethreeresistors.parallelcircuit?V�3.3V�4.7V�3.9V�11.9V1111�������RR1R2R313.Astudentmakesavoltagedividerfroma45-Vbattery,a475-k�resistor,anda235-k����1��1�1120.0�60.0�40.0�resistor.Theoutputismeasuredacrossthesmallerresistor.Whatisthevoltage?R�20.0�VRB(45V)(235k�)b.WhatisthecurrentthroughtheentireV�����B��RA�RB475k��235k��15Vcircuit?14.Selectaresistortobeusedaspartofavolt-I���V�12.0V�0.600AR20.0�agedivideralongwitha1.2-k�resistor.Thedropacrossthe1.2-k�resistoristobe2.2Vc.Whatisthecurrentthrougheachbranchwhenthesupplyis12V.ofthecircuit?VRV12.0VBI��VB���1��R1120.0��0.100ARA�RBV12.0VVRI��R�B2��R60.0��0.200AA��VRB2BV12.0V(12.0V)(1.2k�)I3���R40.0���0.300A����1.2k�32.2V17.Supposethatoneofthe15.0-�resistorsin�5.3k�problem15isreplacedbya10.0-�resistor.a.Doestheequivalentresistancechange?page626Ifso,how?15.Three15.0-�resistorsareconnectedinpar-Yes,itgetssmaller.allelandplacedacrossa30.0-Vbattery.b.Doestheamountofcurrentthroughthea.Whatistheequivalentresistanceoftheentirecircuitchange?Ifso,inwhatway?parallelcircuit?Yes,itgetslarger.1111�������RR1R2R3c.Doestheamountofcurrentthroughtheother15.0-�resistorschange?Ifso,111������how?15.0�15.0�15.0�No,itremainsthesame.Currents3��15.0�areindependent.R�5.00�18.A150-�branchinacircuitmustbereducedb.Whatisthecurrentthroughtheentireto93�.Aresistorwillbeaddedtothiscircuit?branchofthecircuittomakethischange.V30.0VWhatvalueofresistanceshouldbeusedandI�����6.00AR5.00�howmusttheresistorbeconnected?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.WhatisthecurrentthrougheachbranchAparallelresistorwillberequiredtoofthecircuit?reducetheresistance.V30.0VI�����2.00A1�1�1R115.0����RRARBPhysics:PrinciplesandProblemsSolutionsManual465
469Chapter23continuedI11111T�I1�I2�I3�I4���������RARRB93�150��120mA�250mA�380mA�2.1R2�AA�2.4�102.4�102�inparallelwiththe150-��0.12A�0.25A�0.38A�2.1Aresistance�2.9A19.A12-�,2-Wresistorisconnectedinparal-22.TotalCurrentAseriescircuithasfourlelwitha6.0-�,4-Wresistor.Whichwillresistors.Thecurrentthroughoneresistorisbecomehotterifthevoltageacrossthem810mA.Howmuchcurrentissuppliedbykeepsincreasing?thesource?Neither.Theybothreachmaximumdis-810mA.Currentisthesameevery-sipationatthesamevoltage.whereinaseriescircuit.V2P��23.CircuitsAswitchisconnectedinseriesRwitha75-Wbulbtoasourceof120V.V��PR�a.WhatisthepotentialdifferenceacrossThevoltageisequalacrossparalleltheswitchwhenitisclosed(turnedon)?resistors,so:0V;V�IRwithR�0V��P�1R1��P�2R2b.Whatisthepotentialdifferenceacross���(2W)(12��)theswitchifanother75-Wbulbisaddedinseries?���(4W)(6.0��)�0V;V�IRwithR�0�5Vmaximum24.CriticalThinkingThecircuitinFigure23-8hasfouridenticalresistors.SupposethataSectionReviewwireisaddedtoconnectpointsAandB.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.23.1SimpleCircuitsAnswerthefollowingquestions,andexplainyourreasoning.pages617–626page62620.CircuitTypesCompareandcontrasttheRRvoltagesandthecurrentsinseriesandpar-�allelcircuits.ABThestudent’sanswershouldinclude�thefollowingideas:RR(1)Inaseriescircuit,thecurrentineachofthedevicesisthesame,andthesumofthedevicevoltagedropsequals■Figure23-8thesourcevoltage.a.Whatisthecurrentthroughthewire?(2)Inaparallelcircuit,thevoltagedrop0A;thepotentialsofpointsAandBacrosseachdeviceisthesameandthearethesame.sumofthecurrentsthrougheachloopb.Whathappenstothecurrentthroughequalsthesourcecurrent.eachresistor?nothing21.TotalCurrentAparallelcircuithasfourbranchcurrents:120mA,250mA,380mA,c.Whathappenstothecurrentdrawnand2.1A.Howmuchcurrentissuppliedfromthebattery?bythesource?nothing466SolutionsManualPhysics:PrinciplesandProblems
470Chapter23continuedd.Whathappenstothepotentialdiffer-SectionReviewenceacrosseachresistor?nothing23.2ApplicationsofCircuitspages627–631page631PracticeProblemsRefertoFigure23-13forquestions29–33,and35.Thebulbsinthecircuitareidentical.23.2ApplicationsofCircuitspages627–631Apage630BI3AI1I2A25.Aseries-parallelcircuithasthreeresistors:onedissipates2.0W,thesecond3.0W,andAthethird1.5W.Howmuchcurrentdoes12thecircuitrequirefroma12-Vbattery?�CByconservationofenergy(andpower):V�3PT�P1�P2�P3�2.0W�3.0W�1.5W■Figure23-13�6.5WP29.BrightnessHowdothebulbbrightnessesT�IVcompare?PT6.5WI�����0.54ABulbs2and3areequalinbrightnessV12Vbutdimmerthanbulb1.26.Thereare11lightsinseries,andtheyareinserieswithtwolightsinparallel.Ifthe1330.CurrentIfI3measures1.7AandI1mea-lightsareidentical,whichofthemwillburnsures1.1A,howmuchcurrentisflowinginbrightest?bulb2?The11lightsinserieswillburnI3�I1�I2brighter.TheparallellightseachwillIconducthalfofthecurrentoftheseries2�I3�I1�1.7A�1.1A�0.6Alightsandtheywillburnatone-fourth31.CircuitsinSeriesThewireatpointCistheintensityoftheserieslightssincebrokenandasmallresistorisinsertedinP�I2R.serieswithbulbs2and3.Whathappenstothebrightnessesofthetwobulbs?Explain.27.Whatwillhappentothecircuitinproblem26ifoneoftheparallellightsburnsout?Bothdimequally.Thecurrentineachisreducedbythesameamount.Then,alloftheworkinglightsareinseries.The12workinglightswillburn32.BatteryVoltageAvoltmeterconnectedwithequalintensity.acrossbulb2measures3.8V,andavolt-meterconnectedacrossbulb3measures28.Whatwillhappentothecircuitinproblem4.2V.Whatisthebatteryvoltage?26ifoneoftheparallellightsshortsout?Thesebulbsareinseries,so:Then,theshortedlightwillreducetheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.voltageacrossitselfanditsparallelVT�V1�V2�3.8V�4.2V�8.0Vcompanionto0.The11serieslightswillburnwithequal,butincreased,intensityandthetwoparallellightswillgoout.Physics:PrinciplesandProblemsSolutionsManual467
471Chapter23continued33.CircuitsUsingtheinformationfromprob-MasteringConceptslem32,determineifbulbs2and3arepage636identical.37.WhyisitfrustratingwhenonebulbburnsNo.Identicalbulbsinserieswouldhaveoutonastringofholidaytreelightscon-identicalvoltagedropssincetheircur-nectedinseries?(23.1)rentsarethesame.Whenonebulbburnsout,thecircuitisopenandallthebulbsgoout.34.CircuitProtectionDescribethreecom-monsafetydevicesassociatedwithhouse-38.Whydoestheequivalentresistancedecreaseholdwiring.asmoreresistorsareaddedtoaparallelfuses,circuitbreakers,ground-faultcircuit?(23.1)circuitinterruptersEachnewresistorprovidesanaddition-alpathforthecurrent.35.CriticalThinkingIsthereawaytomakethethreebulbsinFigure23-13burnwith39.Severalresistorswithdifferentvaluesareequalintensitywithoutusinganyadditionalconnectedinparallel.Howdothevaluesofresistors?Explain.theindividualresistorscomparewiththeYes.Becauseintensityisproportionalequivalentresistance?(23.1)topower,itwouldbenecessarytouseTheequivalentresistancewillbelessabulbatlocation1thathasfourtimesthanthatofanyoftheresistors.theoperatingresistanceofeachofthoseatlocations2and3.40.WhyishouseholdwiringconstructedinV2/4R�(V/2)2/Rparallelinsteadofinseries?(23.1)Appliancesinparallelcanberuninde-pendentlyofoneanother.ChapterAssessment41.WhyisthereadifferenceinequivalentConceptMappingresistancebetweenthree60-�resistorscon-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page636nectedinseriesandthree60-�resistors36.Completetheconceptmapusingthefol-connectedinparallel?(23.1)lowingterms:seriescircuit,R�R1�R2�Inaseriescircuit,thecurrentisR3,constantcurrent,parallelcircuit,constantopposedbyeachresistanceinturn.Thepotential.totalresistanceisthesumoftheresis-tors.Inaparallelcircuit,eachresis-Resistorsincircuitstanceprovidesanadditionalpathforcurrent.Theresultisadecreaseintotalresistance.seriescircuitTypeofcircuitparallelcircuit42.Comparetheamountofcurrententeringajunctioninaparallelcircuitwiththatleav-ingthejunction.(AjunctionisapointconstantconstantwherethreeormoreconductorsarePrinciplecurrentpotentialjoined.)(23.1)Theamountofcurrententeringajunc-tionisequaltotheamountofcurrent111R�R1�R2�R3�...Resistance�R���R���R��...12leaving.468SolutionsManualPhysics:PrinciplesandProblems
472Chapter23continued43.ExplainhowafusefunctionstoprotectanApplyingConceptselectriccircuit.(23.2)page636Thepurposeofafuseistopreventcon-48.Whathappenstothecurrentintheotherductorsfrombeingoverloadedwithcur-twolampsifonelampinathree-lamprent,causingfiresduetooverheating.Aseriescircuitburnsout?fuseissimplyashortlengthofwirethatIfoneofthelampfilamentsburnsout,willmeltfromtheheatingeffectifthethecurrentwillceaseandallthelampscurrentexceedsacertainmaximum.willgoout.44.Whatisashortcircuit?Whyisashortcir-49.Supposetheresistor,Rcuitdangerous?(23.2)A,inthevoltagedividerinFigure23-4ismadetobeavari-Ashortcircuitisacircuitthathasableresistor.Whathappenstothevoltageextremelylowresistance.Ashortcir-output,VB,ofthevoltagedividerifthecuitisdangerousbecauseanypotentialresistanceofthevariableresistorisdifferencewillproducealargecurrent.increased?TheheatingeffectofthecurrentcanVcauseafire.B�VRB/(RA�RB).AsRAincreases,VBwilldecrease.45.Whyisanammeterdesignedtohaveavery50.CircuitAcontainsthree60-�resistorsinlowresistance?(23.2)series.CircuitBcontainsthree60-�resis-Anammetermusthavelowresistancetorsinparallel.Howdoesthecurrentinthebecauseitisplacedinseriesinthecir-second60-�resistorofeachcircuitchangecuit.Ifitsresistancewerehigh,itwouldifaswitchcutsoffthecurrenttothefirstsignificantlychangethetotalresistance60-�resistor?ofthecircuitandthusservetoreduceCircuitA:Therewillbenocurrentinthethecurrentinthecircuit,therebychang-resistor.ingthecurrentitismeanttomeasure.CircuitB:Thecurrentintheresistorwill46.Whyisavoltmeterdesignedtohaveaveryremainthesamehighresistance?(23.2)51.WhathappenstothecurrentintheotherAvoltmeterisplacedinparallelwiththetwolampsifonelampinathree-lamppar-portionofthecircuitwhosedifferenceallelcircuitburnsout?inpotentialistobemeasured.Avolt-Ifoneofthefilamentsburnsout,themetermusthaveveryhighresistanceresistanceandthepotentialdifferenceforthesamereasonthatanammeteracrosstheotherlampswillnotchange;haslowresistance.Ifthevoltmeterhadtherefore,theircurrentswillremainthelowresistance,itwouldlowertheresis-same.tanceoftheportionofthecircuititisacrossandincreasethecurrentinthe52.Anengineerneedsa10-�resistorandacircuit.Thiswouldproduceahigher15-�resistor,butthereareonly30-�resis-voltagedropacrossthepartofthecir-torsinstock.Mustnewresistorsbepur-cuitwherethevoltmeterislocated,chased?Explain.changingthevoltageitismeasuring.No,the30-�resistorscanbeusedinCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.47.Howdoesthewayinwhichanammeterisparallel.Three30-�resistorsinparallelconnectedinacircuitdifferfromthewayinwillgivea10-�resistance.Two30-�whichavoltmeterisconnected?(23.2)resistorsinparallelwillgivea15-�resistance.Anammeterisconnectedinseries;avoltmeterisconnectedinparallel.Physics:PrinciplesandProblemsSolutionsManual469
473Chapter23continued53.Ifyouhavea6-Vbatteryandmany1.5-Vf.Addingaresistortothecircuitincreasesbulbs,howcouldyouconnectthemsothatthetotalresistance.theylightbutdonothavemorethan1.5Vseriesacrosseachbulb?g.IfthecurrentthroughoneresistorintheConnectfourofthebulbsinseries.circuitgoestozero,thereisnocurrentThevoltagedropacrosseachwillbeintheentirecircuit.(6.0V)/4�1.5V.series54.Twolampshavedifferentresistances,oneh.Ifthecurrentthroughoneresistorinthelargerthantheother.circuitgoestozero,thecurrentthroughallotherresistorsremainsthesame.a.Ifthelampsareconnectedinparallel,whichisbrighter(dissipatesmoreparallelpower)?i.Thisformissuitableforhousewiring.Thelampwiththelowerresistance:parallelP�IVandI�V/R,soP�V2/R.Becausethevoltagedropisthe56.HouseholdFusesWhyisitdangeroustosameacrossbothlamps,thesmallerreplacethe15-AfuseusedtoprotectaRmeanslargerP,andthuswillbehouseholdcircuitwithafusethatisratedatbrighter.30A?b.Whenthelampsareconnectedinseries,The30-Afuseallowsmorecurrenttowhichlampisbrighter?flowthroughthecircuit,generatingmoreheatinthewires,whichcanbeThelampwiththehigherresistance;P�IVandV�IR,soP�I2R.dangerous.Becausethecurrentisthesameinbothlamps,thelargerRmeanslarg-MasteringProblemserP,andthuswillbebrighter.23.1SimpleCircuitspages637–63855.Foreachofthefollowing,writetheformofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Level1circuitthatapplies:seriesorparallel.57.Ammeter1inFigure23-14reads0.20A.a.Thecurrentisthesameeverywherethroughouttheentirecircuit.A122�seriesA2b.Thetotalresistanceisequaltothesum�oftheindividualresistances.Vseries�15�c.Thevoltagedropacrosseachresistorinthecircuitisthesame.A3parallel■Figure23-14d.Thevoltagedropinthecircuitispro-portionaltotheresistance.a.Whatshouldammeter2indicate?series0.20A,becausecurrentisconstantinaseriescircuit.e.Addingaresistortothecircuitdecreasesthetotalresistance.b.Whatshouldammeter3indicate?parallel0.20A,becausecurrentisconstantinaseriescircuit.470SolutionsManualPhysics:PrinciplesandProblems
474Chapter23continued58.Calculatetheequivalentresistanceofthese64.A22-�lampanda4.5-�lampareconnect-series-connectedresistors:680�,1.1k�,edinseriesandplacedacrossapotentialdif-and10k�.ferenceof45VasshowninFigure23-15.R�680��1100��10,000��12k�22��59.Calculatetheequivalentresistanceofthese45V4.5�parallel-connectedresistors:680�,1.1k�,�and10.2k�.1111�������RR1RR■Figure23-1523a.Whatistheequivalentresistanceofthe1R����circuit?111����������0.68k�1.1k�10.2k�22��4.5��26��0.40k�b.Whatisthecurrentinthecircuit?V45V60.Aseriescircuithastwovoltagedrops:5.50VI���R�27��1.7Aand6.90V.Whatisthesupplyvoltage?c.WhatisthevoltagedropacrosseachV�5.50V�6.90V�12.4Vlamp?V�IR�(1.7A)(22�)�37V61.Aparallelcircuithastwobranchcurrents:V�IR�(1.7A)(4.5�)�7.7V3.45Aand1.00A.Whatisthecurrentintheenergysource?d.Whatisthepowerdissipatedineachlamp?I�3.45A�1.00A�4.45AP�IV�(1.7A)(37V)�63WP�IV�(1.7A)(7.7V)�13WLevel262.Ammeter1inFigure23-14reads0.20A.65.RefertoFigure23-16toanswerthefollow-a.Whatisthetotalresistanceofthecircuit?ingquestions.R�R1�R2�15��22��37�V1b.Whatisthebatteryvoltage?V�IR�(0.20A)(37�)�7.4VAc.Howmuchpowerisdeliveredtothe35�22-�resistor?�P�I2R�(0.20A)2(22�)�0.88W10.0V15�V2�d.Howmuchpowerissuppliedbythebattery?P�IV�(0.20A)(7.4V)�1.5W■Figure23-1663.Ammeter2inFigure23-14reads0.50A.a.Whatshouldtheammeterread?a.Findthevoltageacrossthe22-�resistor.R�R1�R2�35��15�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.V�IR�(0.50A)(22�)�11VI�V/Rb.Findthevoltageacrossthe15-�resistor.�(10.0V)/(35��15�)V�IR�(0.50A)(15�)�7.5V�0.20Ac.Whatisthebatteryvoltage?b.Whatshouldvoltmeter1read?V�V1�V2�(11V)�(7.5V)�19VV�IR�(0.20A)(35�)�7.0VPhysics:PrinciplesandProblemsSolutionsManual471
475Chapter23continuedc.Whatshouldvoltmeter2read?67.ForFigure23-18,thebatterydevelops110V.V�IR�(0.20A)(15�)�3.0Vd.HowmuchenergyissuppliedbytheA2A3A4batteryperminute?�VE�Pt�20.0�50.0�10.0��VIt�(10.0V)(0.20A)(1min)(60s/min)A1�120J■Figure23-1866.ForFigure23-17,thevoltmeterreads70.0V.a.Whichresistoristhehottest?10.0�.SinceP�V2/RandVisVconstantinaparallelcircuit,thesmallestresistorwilldissipatetheAmostpower.35��b.Whichresistoristhecoolest?V15�50.0�.SinceP�V2/RandVis�constantinaparallelcircuit,the50�largestresistorwilldissipatetheleastpower.■Figure23-17c.Whatwillammeter1read?a.Whichresistoristhehottest?1111�������50�.SinceP�I2RandIiscon-RR1R2R3stantinaseriescircuit,thelargest1R���valueofresistancewillproducethe111����������RRRmostpower.123b.Whichresistoristhecoolest?1Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�����15�.SinceP�I2RandIiscon-��1���1���1��20.0�50.0�10.0�stantinaseriescircuit,thesmallest�5.88�valueofresistancewillproducetheV1.1�102Vleastpower.I������19AR5.88�c.Whatwilltheammeterread?d.Whatwillammeter2read?UseOhm’slaw:I�V/RV1.1�102VI������5.5A�(70.0V)/(35�)R20.0��2.0Ae.Whatwillammeter3read?d.WhatisthepowersuppliedbytheV1.1�102VI������2.2Abattery?R50.0�First,findthetotalresistance:f.Whatwillammeter4read?R�R1�R2�R3V1.1�102VI������11AR10.0��35��15��50�68.ForFigure23-18,ammeter3reads0.40A.�0.1k�a.Whatisthebatteryvoltage?P�I2RV�IR�(0.40A)(50.0�)�2.0�101V�(2.0A)2(0.1k�)(1000�/k�)�4�102W472SolutionsManualPhysics:PrinciplesandProblems
476Chapter23continuedb.Whatwillammeter1read?b.Whatistheresistanceofasinglelight?Findtheequivalentresistance:Risthesumoftheresistancesof111118lamps,soeachresistanceis�������RR1R2R32.3�102����13�118R�����1���1���1��c.Whatpowerisdissipatedbyeachlight?RRR12364W��3.6W118�����111����������20.0�50.0�10.0�72.Oneofthelightsinproblem71burnsout.1Thelightshortsoutthebulbfilamentwhen��0.17�itburnsout.Thisdropstheresistanceofthelamptozero.�5.88�1Va.WhatistheresistanceofthelightstringV2.0�10I������3.4Anow?R5.88�c.Whatwillammeter2read?Therearenow17lampsinseries1Vinsteadof18lamps.TheresistanceV2.0�10I������1.0AR20.0�is���17(2.3�102�)�2.2�102�18d.Whatwillammeter4read?b.Findthepowerdissipatedbythestring.V2.0�101VI������2.0AV2(120V)2R10.0�P�����2��65WR2.2�1069.Whatisthedirectionoftheconventionalcur-c.Didthepowerincreaseordecreaserentinthe50.0-�resistorinFigure23-18?whenthebulbburnedout?downItincreased.70.Theloadacrossabatteryconsistsoftwo73.A16.0-�anda20.0-�resistorareconnect-resistors,withvaluesof15�and47�,edinparallel.Adifferenceinpotentialofconnectedinseries.40.0Visappliedtothecombination.a.Whatisthetotalresistanceoftheload?a.ComputetheequivalentresistanceofR�R1�R2�15��47�theparallelcircuit.�62��1���1�1RR1R2b.Whatisthevoltageofthebatteryifthecurrentinthecircuitis97mA?1R���11V�IR�(97mA)(62�)�6.0V�������RR12171.HolidayLightsAstringof18identical���11holidaytreelightsisconnectedinseriestoa��16.0����20.0���120-Vsource.Thestringdissipates64W.�8.89�a.Whatistheequivalentresistanceoftheb.Whatisthetotalcurrentinthecircuit?lightstring?V40.0V2I�����4.50ACopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.P��VR8.89�Reqc.Whatisthecurrentinthe16.0-�V2(120V)22�resistor?R��eq��P64W�2.3�10V40.0VI��1��R116.0��2.50APhysics:PrinciplesandProblemsSolutionsManual473
477Chapter23continued74.Amyneeds5.0Vforanintegrated-circuitc.A12-�hairdryerispluggedintotheexperiment.Sheusesa6.0-Vbatteryandsameoutlet.Findtheequivalentresis-tworesistorstomakeavoltagedivider.Onetanceofthetwoappliances.resistoris330�.Shedecidestomakethe111�����otherresistorsmaller.WhatvalueshoulditRRARBhave?1R���VR211V2����������R1�R2RARBVR12���R1���VR2��1���1��252�12���(6.0V)(330���)330��66��9.8�5.0Vd.Findthevoltagedropacrossthetelevi-75.Peteisdesigningavoltagedividerusingasionandthehairdryer.12-Vbatteryanda82-�resistorasRB.VRA(120V)(9.8�)WhatresistorshouldbeusedasRAiftheV1����R9.8����2.5��96VA�RBoutputvoltageacrossRBistobe4.0V?VRV��B23.2ApplicationsofCircuitsB�RA�RBpages638–639VRBLevel1R�A�RB�V77.RefertoFigure23-19andassumethatallBVRtheresistorsare30.0�.FindtheequivalentR�BA��VRBresistance.B(12V)(82�)����82�4.0V�IA�1.6�102�IBIC�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Level3■Figure23-1976.TelevisionAtypicaltelevisiondissipates275Wwhenitispluggedintoa120-VTheparallelcombinationofthetwooutlet.30.0-�resistorshasanequivalentresistanceof15.0�.a.Findtheresistanceofthetelevision.2SoR�30.0��15.0��45.0�VVP�IVandI��,soP��,orRR78.RefertoFigure23-19andassumethateachV2(120V)2R�����52�resistordissipates120mW.FindthetotalP275Wdissipation.b.Thetelevisionand2.5-�wiresconnect-P�3(120mW)�360mWingtheoutlettothefuseformaseriescir-cuitthatworkslikeavoltagedivider.Find79.RefertoFigure23-19andassumethatthevoltagedropacrossthetelevision.IA�13mAandIB�1.7mA.FindIC.VRV��AIA�RC�IA�IBA�RB�13mA�1.7mA(120V)(52�)���52��2.5��11mA�110V474SolutionsManualPhysics:PrinciplesandProblems
478Chapter23continued80.RefertoFigure23-19andassumethatHalfthetotalcurrentisineachIparallelbranchbecausethesumofB�13mAandIC�1.7mA.FindIA.ItheresistancesineachbranchareA�IB�ICequal.�13mA�1.7mAP�I2R�(0.25A)2(30.0�)�1.9W�15mAP�I2R�(0.25A)2(20.0�)�1.2WLevel2P�I2R�(0.25A)2(10.0�)�0.62W81.RefertoFigure23-20toanswerthefollow-P�I2R�(0.25A)2(40.0�)�2.5Wingquestions.The25.0-�resistoristhehottest.25.0�The10.0-�resistoristhecoolest.30.0�10.0��82.Acircuitcontainssix60-Wlampswitha25Vresistanceof240-�eachanda10.0-��20.0�40.0�heaterconnectedinparallel.Thevoltageacrossthecircuitis120V.Findthecurrentinthecircuitforthefollowingsituations.■Figure23-20a.Fourlampsareturnedon.a.Determinethetotalresistance.11111���������The30.0-�and20.0-�resistorsareRRRRR1234inseries.111�������R1�30.0��20.0��50.0�240�240�240�The10.0-�and40.0-�resistorsare�1240�inseries.4R��2�10.0��40.0��50.0�240�R1andR2areinparallel.R���240�0.060k�4111�����V120VRR1R2I������2.0AR0.060k�1b.Allofthelampsareturnedon.R���11�������16RR12���R240�1���11240��������R���0.040k�50.0�50.0�6�25.0�andisinserieswiththeI���V��120V�3.0AR0.040k�25.0-�resistorc.Sixlampsandtheheaterareoperating.RTotal�25.0��25.0��50.0�111b.Determinethecurrentthroughthe25-��R��0.040k���10.0��resistor.5���Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.useOhm’slawandRTotal4.0�101�V25V4.0�101�I�����0.50AR����8.0�RTotal50.0�5c.Whichresistoristhehottest?Coolest?V120VI�����15AR8.0�P�I2R�(0.50A)2(25.0�)�6.25WPhysics:PrinciplesandProblemsSolutionsManual475
479Chapter23continued83.Ifthecircuitinproblem82hasa12-Afuse,86.HomeCircuitAtypicalhomecircuitiswillthefusemeltifallthelampsandtheshowninFigure23-21.Thewirestotheheaterareon?kitchenlampeachhavearesistanceofYes.The15-Acurrentwillmeltthe12-A0.25�.Thelamphasaresistanceoffuse.0.24k�.Althoughthecircuitisparallel,theleadlinesareinserieswitheachof84.Duringalaboratoryexercise,youaresup-thecomponentsofthecircuit.pliedwithabatteryofpotentialdifference0.25�KitchenV,twoheatingelementsoflowresistancelight240�thatcanbeplacedinwater,anammeterofverysmallresistance,avoltmeterofextreme-SwitchPowerboxlyhighresistance,wiresofnegligibleresis-saw120Vtance,abeakerthatiswellinsulatedandhasnegligibleheatcapacity,and0.10kgofwaterWalloutletsat25°C.Bymeansofadiagramandstan-0.25�dardsymbols,showhowthesecomponents■Figure23-21shouldbeconnectedtoheatthewaterasa.Computetheequivalentresistanceofrapidlyaspossible.thecircuitconsistingofjustthelampAandtheleadlinestoandfromthelamp.�HeatingHeatingVelementelementVR�0.25��0.25��0.24k��#1#2�0.24k�b.Findthecurrenttothelamp.V120V85.Ifthevoltmeterusedinproblem84holdsI�����0.50AR0.24k�steadyat45Vandtheammeterreadingc.Findthepowerdissipatedinthelamp.holdssteadyat5.0A,estimatethetimeinsecondsrequiredtocompletelyvaporizetheP�IV�(0.50A)(120V)�6.0�101WCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.waterinthebeaker.Use4.2kJ/kg�°Casthespecificheatofwaterand2.3�106J/kgasMixedReviewtheheatofvaporizationofwater.page639�Q�mC�TLevel187.Aseriescircuithastwovoltagedrops:3.50�(0.10kg)(4.2kJ/kg�°C)(75°C)Vand4.90V.Whatisthesupplyvoltage?�32kJ(energyneededtoraiseV�3.50V�4.90V�8.40Vtemperatureofwaterto100°C)�Q�mH6J/kg)88.Aparallelcircuithastwobranchcurrents:v�(0.10kg)(2.3�102kJ(energyneededto1.45Aand1.00A.Whatisthecurrentin�2.3�10theenergysource?vaporizethewater)I�1.45A�1.00A�2.45A�Q2kJtotal�32kJ�2.3�102kJ(totalenergyneed-89.Aseries-parallelcircuithasthreeresistors,�2.6�10dissipating5.50W,6.90W,and1.05W,ed)Energyisprovidedattherespectively.Whatisthesupplypower?rateofP�5.50W�6.90W�1.05W�13.45WP�IV�(5.0A)(45V)�0.23kJ/s.Thetimerequiredis2.6�102kJ3st����1.1�100.23kJ/s476SolutionsManualPhysics:PrinciplesandProblems
480Chapter23continuedLevel2c.avoltmeterwitharesistanceof10�106�90.DeterminethemaximumsafepowerinThevoltmeterresistanceactsineachofthree150-�,5-Wresistorsparallel:connectedinseries.111Allwilldissipatethesamepower.�����RBR1R2P�(3)(5W)�15W11������47�103�10�106�91.Determinethemaximumsafepowerin1eachofthree92-�,5-Wresistorsconnected���2.1�10�5�inparallel.REachresistorwilldevelopthesameB�47k�power.VRBV��B�RP�(3)(5W)�15WA�RB(12V)(47k�)���92.Avoltagedividerconsistsoftwo47-k�47k��47k�resistorsconnectedacrossa12-Vbattery.�6.0VDeterminethemeasuredoutputfortheThemeterapproachestheidealfollowing.voltmeter.a.anidealvoltmeterVRV��BB�RLevel3A�RB93.Determinethemaximumsafevoltagethat(12V)(47k�)canbeappliedacrossthethreeseriesresistors���47k��47k�inFigure23-22ifallthreeareratedat5.0W.�6.0V92�150�220�b.avoltmeterwitharesistanceof85k�Thevoltmeterresistanceactsin■Figure23-22parallel:Currentisconstantinaseriescircuit,111�����sothelargestresistorwilldeveloptheRRRB12mostpower.11���47k��85k�P�I2R1P5.0W����5I���������0.151A3.3�10�R220�R1k�Thetotalresistanceisnowneeded.B�3.0�10VRBRTotal�92��150��220�V��B�RA�RB�462�(12V)(3.0�101k�)UseOhm’slawtofindthevoltage.����47k��3.0�101k�V�IR�4.7V�(0.151A)(462�)�7.0�101VCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.94.Determinethemaximumsafetotalpowerforthecircuitinproblem93.1V)2P�V2/R����(7.0�1011W462�Physics:PrinciplesandProblemsSolutionsManual477
481Chapter23continued95.Determinethemaximumsafevoltagethat97.ApplyConceptsThree-waylamps,ofthecanbeappliedacrossthreeparallelresistorstypeinFigure23-24,havingaratingofof92�,150�,and220�,asshownin50W,100W,and150W,arecommon.Figure23-23,ifallthreeareratedat5.0W.Drawfourpartialschematicdiagramsthatshowthelampfilamentsandtheswitch92�positionsforeachbrightnesslevel,aswellastheoffposition.(Youdonotneedtoshow150�theenergysource.)Labeleachdiagram.220�■Figure23-23The92-�resistorwilldevelopthemostpowerbecauseitwillconductthemostcurrent.V2P��RV��PR����(5.0W)(92��)��21VThinkingCritically■Figure23-24pages639–64096.ApplyMathematicsDeriveequationsforLowerRtheresistanceoftwoequal-valueresistorsinHigherRparallel,threeequal-valueresistorsinparallel,andNequal-valueresistorsinparallel.1112100W�������Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Req2RRR150W50WRR�eq2�211113���������98.ApplyConceptsDesignacircuitthatwillReq3RRRRlightonedozen12-Vbulbs,alltothecor-Rrect(same)intensity,froma48-Vbattery.R�eq3�3a.DesignArequiresthatshouldonebulbRRburnout,allotherbulbscontinuetoeqN��Nproducelight.48V478SolutionsManualPhysics:PrinciplesandProblems
482Chapter23continuedb.DesignBrequiresthatshouldonebulbburnout,thosebulbsthatcontinueworkingmustproducethecorrectintensity.48Vc.DesignCrequiresthatshouldonebulbburnout,oneotherbulbalsowillgoout.48Vd.DesignDrequiresthatshouldonebulbburnout,eithertwootherswillgooutornootherswillgoout.48V99.ApplyConceptsAbatteryconsistsofanidealsourceofpotentialdifferenceinserieswithasmallresistance.Theelectricenergyofthebatteryisproducedbychemicalreactionsthatoccurinthebattery.However,thesereactionsalsoresultinasmallresistancethat,unfortunately,cannotbecompletelyeliminated.Aflash-lightcontainstwobatteriesinseries,asshowninFigure23-25.Eachhasapoten-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tialdifferenceof1.50Vandaninternalresistanceof0.200�.Thebulbhasaresistanceof22.0�.Physics:PrinciplesandProblemsSolutionsManual479
483Chapter23continuedBatteryBatteryb.Theleadsarenowconnectedtoanunknownresistance.Whatresistancewouldproduceacurrentofhalf-scale,0.50mA?Quarter-scale,0.25mA?1.50V0.200�1.50V0.200�Three-quarters-scale,0.75mA?V6.0VR������12k�I0.50�10�3A22.0�andRT�R1�Re,soRe�RT�R1■Figure23-25�12k��6.0k�a.Whatisthecurrentthroughthebulb?�6.0k�Thecircuithastwo1.50-VbatteriesinV6.0Vserieswiththreeresistors:0.200�,R������24k�I0.25�10�3A0.200�,and22.0�.TheequivalentandRresistanceis22.4�.Thecurrentise�RT�R1V�24k��6.0k�I��R�18k�2(1.50)V����V6.0V(2(0.200�)�22.0�)R������8.0k�I0.75�10�3A�0.134AandRe�RT�R1b.Howmuchpowerdoesthebulb�8.0k��6.0k�dissipate?�2.0k�Thepowerdissipatedisc.Istheohmmeterscalelinear?Explain.P�I2RNo.Zeroohmsisatfull-scale,6k��(0.134A)2(22.0�)isatmidscale,andinfinite�(oropen-circuit)isatzero-scale.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.395Wc.HowmuchgreaterwouldthepowerbeifWritinginPhysicsthebatterieshadnointernalresistance?page640V2(3.00V)2P�IV�����0.409W101.ResearchGustavKirchhoffandhislaws.R22.0�Writeaone-pagesummaryofhowthey�P�0.409W�0.395W�0.014WapplytothethreetypesofcircuitsPowerwouldbe0.014Wgreater.presentedinthischapter.Keyideasare:100.ApplyConceptsAnohmmeterismadebyconnectinga6.0-Vbatteryinserieswith(1)Kirchhoff’sVoltageLaw(KVL)isanadjustableresistorandanidealamme-conservationofenergyappliedtoter.Theammeterdeflectsfull-scalewithaelectriccircuits.currentof1.0mA.Thetwoleadsare(2)Kirchhoff’sCurrentLaw(KCL)istouchedtogetherandtheresistanceisconservationofchargeappliedtoadjustedsothat1.0mAflows.electriccircuits.a.Whatistheresistanceoftheadjustable(3)KVLstatesthatthealgebraicsumresistor?ofvoltagedropsaroundaclosedV�IRloopiszero.Inaseriescircuitthereisoneclosedloop,andthesumofV6.0VR���I���3�6.0k�voltagedropsintheresistances1.0�10Aequalsthesourcevoltage.Ina480SolutionsManualPhysics:PrinciplesandProblems
484Chapter23continuedparallelcircuit,thereisaclosede.Whatisthefrequencydetectedbyanloopforeachbranch,andKVLobserverlocateddirectlybehindtheimpliesthatthevoltagedropinairplane?eachbranchisthesame.f�v/�(4)KCLstatesthatthealgebraicsum�(340m/s)/(1.50m)ofcurrentsatanodeiszero.Ina�230Hz,orseriescircuit,ateverypointthev�vcurrentinequalscurrentout;there-f�dd�fs��v�vfore,thecurrentisthesameevery-swhere.Inaparallelcircuit,thereis340m/s�0�(340Hz)�����340m/s�(�170m/s)acommonnodeateachendofthebranches.KCLimpliesthatthesum�230Hzofthebranchcurrentsequalsthe103.Anobjectislocated12.6cmfromacon-sourcecurrent.vexmirrorwithafocallengthofCumulativeReview�18.0cm.Whatisthelocationoftheobject’simage?(Chapter17)page640111102.AirplaneAnairplaneflyingthroughstill�����fdodiairproducessoundwaves.Thewavefrontsinfrontoftheplanearespaced0.50mdofd�apartandthosebehindtheplanearei�do�fspaced1.50mapart.Thespeedofsound(12.6cm)(�18.0cm)����is340m/s.(Chapter15)12.6cm�(�18.0cm)a.Whatwouldbethewavelengthofthe��7.41cmsoundwavesiftheairplanewerenotmoving?104.Thespeedoflightinaspecialpieceof1.00mglassis1.75�108m/s.Whatisitsindexofrefraction?(Chapter18)b.Whatisthefrequencyofthesoundwavesproducedbytheairplane?cn��vf�v/��(340m/s)/(1.00m)�340Hz3.00�108m/s���c.Whatisthespeedoftheairplane?1.75�108m/sTheairplanemovesforward0.50m�1.71forevery1.00mthatthesoundwavesmove,soitsspeedisone-105.MonocleAnantireflectivecoatingwithanhalfthespeedofsound,170m/s.indexofrefractionof1.4isappliedd.Whatisthefrequencydetectedbyantoamonoclewithanindexofrefractionobserverlocateddirectlyinfrontoftheof1.52.Ifthethicknessofthecoatingisairplane?75nm,whatis/arethewavelength(s)oflightforwhichcompletedestructivef�v/�interferencewilloccur?(Chapter19)�(340m/s)/(0.50m)Becausen�680Hz,orfilm�nair,thereisaphaseinversiononthefirstreflection.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.v�vdBecausenfd�fs���v�vmonocle�nfilm,thereisasphaseinversiononthesecond340m/s�0reflection.�(340Hz)�����340m/s�170m/sFordestructiveinterference:�680Hz1�2t��m����2nfilmPhysics:PrinciplesandProblemsSolutionsManual481
485Chapter23continued2tn���film1m���2(2)(75nm)(1.4)���1m���21�1��m���(2.1�102nm)2Form�01�1����(2.1�102nm)2�4.2�102nmForm�13�1����(2.1�102nm)2�2.8�102nmThisisanultravioletwavelength,soitisnotlight.Allothervaluesofmgivewavelengthsthatareshorterthanthelight.So��4.2�102nmistheonlywavelengthoflightforwhichdestructiveinterferenceoccurs.106.Twochargesof2.0�10�5Cand8.0�10�6Cexperienceaforcebetweenthemof9.0N.Howfarapartarethetwocharges?(Chapter20)qKqF�K�AqB,sod��A�qBd2��F�(9.0�109N�m2/C2)(2.0�10�5C)(8.0�10�6C)�������������0.40m9.0NCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.107.Afieldstrength,E,ismeasuredadistance,d,fromapointcharge,Q.WhatwouldhappentothemagnitudeofEinthefollowingsituations?(Chapter21)KQE��d2a.distripledE�9b.Qistripled3Ec.bothdandQaretripledE�3d.thetestchargeqistripledE;bydefinition,fieldstrengthisforceperunittestcharge.e.allthree,d,Q,andq,aretripledE�3482SolutionsManualPhysics:PrinciplesandProblems
486Chapter23continued108.Thecurrentflowina12-VcircuitdropsR���3V�(I1�I2)R1R3from0.55Ato0.44A.CalculatethesubstituteVR3�R2�R3changeinresistance.(Chapter22)RRandV���5V�(I1�I2)R1R51�V/I�12V/0.55A�21.8�R5�R4�R5R2�V/I�12V/0.44A�27.3�V�R�RR3�VR5.RemovingR3fromtheleft2�R1numeratorandR5fromtheright12V12Vnumeratorgivesthefollowing:����0.44A0.55AV�(IV�(I��1�I2)R1���1�I2)R1�5.5�RR���2�1����4�1�RR3511ChallengeProblem�R��R���2�1����4�1�RRpage62835Whenthegalvanometer,adeviceusedtomea-R3R5���sureverysmallcurrentsorvoltages,inthiscircuitR2R4measureszero,thecircuitissaidtobebalanced.3.Whichoftheresistorscanbereplacedwithavariableresistorandthenusedtobalancethecircuit?R1R2R4anyresistorbutR1�VAB4.Whichoftheresistorscanbereplacedwith�avariableresistorandthenusedasasensi-R3R5tivitycontrol?Whywouldthisbenecessary?Howwoulditbeusedinpractice?R1.Agalvanometerisasensitiveinstru-1.Yourlabpartnerstatesthattheonlywaytomentandcanbedamagedbytoomuchbalancethiscircuitistomakealltheresis-currentflow.IfR1isadjustable,itissettorsequal.Willthisbalancethecircuit?Isforahighvaluebeforethecircuitistheremorethanonewaytobalancethiscir-energized.Thislimitsthecurrentflowcuit?Explain.throughthegalvanometerifthecircuitYes;yes.Youalsocanbalancethecir-happenstobewayoutofbalance.AscuitbyadjustingtheresistancevaluesthebalancingresistorisadjustedandsothatRasthemeterreadingapproacheszero,7/R3�R4/R5remainsequal.thesensitivitythenisincreasedby2.DeriveageneralequationforabalanceddecreasingR1.circuitusingthegivenlabels.Hint:Treatthecircuitasavoltagedivider.OnedefinitionofbalanceisthatVAB�0.Ifthisisso,thenVR3�VR5.ThesevoltagedropscanbedefinedusingOhm’slaw:Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.VR3�I1R3andVR5�I2R5V�(I��1�I2)R1also,I1�R2�R3V�(IandI��1�I2)R12�R4�R5Physics:PrinciplesandProblemsSolutionsManual483
487
488CHAPTER24MagneticFields4.WhydomagneticcompassessometimesPracticeProblemsgivefalsereadings?24.1Magnets:PermanentandbecauseEarth’smagneticfieldisdis-Temporarytortedbyobjectsmadeofiron,nickel,orpages643–651cobaltinthevicinityofthecompass,andbyoredepositsofthesesamemetalspage6471.Ifyouholdabarmagnetineachhandandbringyourhandsclosetogether,willthepage650forcebeattractiveorrepulsiveifthemag-5.Along,straight,current-carryingwirerunsnetsareheldinthefollowingways?fromnorthtosouth.a.thetwonorthpolesarebroughtclosea.Acompassneedleplacedabovethewiretogetherpointswithitsnorthpoletowardtheeast.Inwhatdirectionisthecurrentrepulsiveflowing?b.anorthpoleandasouthpolearefromsouthtonorthbroughttogetherb.Ifacompassisputunderneaththewire,attractiveinwhichdirectionwillthecompass2.Figure24-7showsfivediskmagnetsfloat-needlepoint?ingaboveeachother.Thenorthpoleofthewesttop-mostdiskfacesup.Whichpolesareonthetopsideofeachoftheothermagnets?6.Howdoesthestrengthofamagneticfield,1cmfromacurrent-carryingwire,comparewitheachofthefollowing?a.thestrengthofthefieldthatis2cmfromthewireBecausemagneticfieldstrengthvariesinverselywiththedistancefromthewire,themagneticfieldat1cmwillbetwiceasstrongasthemagneticfieldat2cm.b.thestrengthofthefieldthatis3cmfromthewireBecausemagneticfieldstrengthvariesinverselywiththedistance■Figure24-7fromthewire,themagneticfieldat1cmwillbethreetimesasstrongassouth,north,south,norththemagneticfieldat3cm.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3.Amagnetattractsanail,which,inturn,attractsmanysmalltacks,asshowninFigure24-3onpage645.Ifthenorthpoleofthepermanentmagnetistheleftend,asshown,whichendofthenailisthesouthpole?thebottom(thepoint)Physics:PrinciplesandProblemsSolutionsManual485
489Chapter24continued7.AstudentmakesamagnetbywindingwireStudentanswersmayvary.Answersaroundanailandconnectingittoabattery,couldincludemagnetsonarefrigeratorasshowninFigure24-13.WhichendofandEarth’smagneticfield.Theeffectsthenail,thepointedendorthehead,willoftheseforcescanbedemonstratedbybethenorthpole?bringinganothermagnet,oramaterialthatcanbemagnetized,nearby.12.MagneticFieldsAcurrent-carryingwireispassedthroughacardonwhichironfilings��aresprinkled.Thefilingsshowthemagneticfieldaroundthewire.Asecondwireisclose■Figure24-13toandparalleltothefirstwire.Thereisanthepointedendidenticalcurrentinthesecondwire.Ifthetwocurrentsareinthesamedirection,how8.Youhaveaspoolofwire,aglassrod,anwillthefirstmagneticfieldbeaffected?ironrod,andanaluminumrod.WhichrodHowwillitbeaffectedifthetwocurrentsshouldyouusetomakeanelectromagnetareinoppositedirections?topickupsteelobjects?Explain.ItwouldbeapproximatelytwiceasUsetheironrod.Ironwouldbeattractedlarge;itwouldbeapproximatelyzero.toapermanentmagnetandtakeonprop-ertiesofamagnet,whereasaluminumor13.DirectionofaMagneticFieldDescribeglasswouldnot.Thiseffectwouldsup-theright-handruleusedtodeterminetheportthemagneticfieldinthewirecoilanddirectionofamagneticfieldaroundathusmakethestrongestelectromagnet.straight,current-carryingwire.Ifyougraspthewirewithyourrighthand,9.Theelectromagnetinproblem8workswell,withyourthumbpointinginthedirectionbutyoudecidethatyouwouldliketomakeitsoftheconventionalcurrent,yourfingersstrengthadjustablebyusingapotentiometercurlinthedirectionofthefield.asavariableresistor.Isthispossible?Explain.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Yes.Connectthepotentiometerin14.ElectromagnetsAglasssheetisplacedserieswiththepowersupplyandtheoveranactiveelectromagnet,andironfil-coil.Adjustingthepotentiometerforingssprinkledonthesheetcreateapatternmoreresistancewilldecreasethecur-onit.Ifthisexperimentisrepeatedwiththerentflowandthestrengthofthefield.polarityofthepowersupplyreversed,whatobservabledifferenceswillresult?Explain.None.ThefilingswouldshowthesameSectionReviewfieldpatternbutacompasswouldshow24.1Magnets:Permanentandthemagneticpolarityreversal.Temporary15.CriticalThinkingImagineatoycontain-pages643–651ingtwoparallel,horizontalmetalrods,onepage651abovetheother.Thetoprodisfreetomove10.MagneticFieldsIsamagneticfieldreal,orupanddown.isitjustameansofscientificmodeling?a.Thetoprodfloatsabovethelowerone.IfFieldlinesarenotreal.Thefieldisreal.thetoprod’sdirectionisreversed,however,itfallsdownontothelowerrod.Explain11.MagneticForcesIdentifysomemagneticwhytherodscouldbehaveinthisway.forcesaroundyou.Howcouldyoudemon-Themetalrodscouldbemagnetsstratetheeffectsofthoseforces?withtheiraxesparallel.Ifthetop486SolutionsManualPhysics:PrinciplesandProblems
490Chapter24continuedmagnetispositionedsothatits19.A40.0-cm-longcopperwirecarriesacur-northandsouthpolesareabovetherentof6.0Aandweighs0.35N.Acertainnorthandsouthpolesofthebottommagneticfieldisstrongenoughtobalancemagnet,itwillberepelledandfloattheforceofgravityonthewire.Whatistheabove.Ifthetopmagnetisturnedstrengthofthemagneticfield?endforend,itwillbeattractedtotheF�BIL,whereF�weightofthewirebottommagnet.F0.35NB������0.15Tb.AssumethatthetoprodwaslostandIL(6.0A)(0.400m)replacedwithanotherone.Inthiscase,20.Howmuchcurrentwillberequiredtopro-thetoprodfallsontopofthebottomduceaforceof0.38Nona10.0cmlengthrodnomatterwhatitsorientationis.ofwireatrightanglestoa0.49-Tfield?WhattypeofreplacementrodmustF�BILhavebeenused?F0.38NIfanordinaryironbarisusedonI��������7.8ABL(0.49T)(0.100m)top,itwillbeattractedtothebottommagnetinanyorientation.page65821.Inwhatdirectiondoesthethumbpointwhenusingthethirdright-handruleforanelectronPracticeProblemsmovingatrightanglestoamagneticfield?24.2ForcesCausedbyoppositetothedirectionoftheelectronMagneticFieldsmotionpages652–65922.Anelectronpassesthroughamagneticfieldpage654atrightanglestothefieldatavelocityof16.Whatisthenameoftheruleusedtopredict4.0�106m/s.Thestrengthofthemagneticthedirectionofforceonacurrent-carryingfieldis0.50T.Whatisthemagnitudeofthewireatrightanglestoamagneticfield?forceactingontheelectron?Identifywhatmustbeknowntousethisrule.F�BqvThirdright-handrule.Thedirectionof�(0.50T)(1.60�10�19C)(4.0�106m/s)thecurrentandthedirectionofthefield�3.2�10�13Nmustbeknown.23.Astreamofdoublyionizedparticles(miss-17.Awirethatis0.50mlongandcarryingaingtwoelectrons,andthus,carryinganetcurrentof8.0Aisatrightanglestoa0.40-Tchargeoftwoelementarycharges)movesatmagneticfield.Howstrongistheforcethatavelocityof3.0�104m/sperpendiculartoactsonthewire?amagneticfieldof9.0�10�2T.WhatistheF�BIL�(0.40N/A�m)(8.0A)(0.50m)magnitudeoftheforceactingoneachion?�1.6NF�Bqv18.Awirethatis75cmlong,carryingacurrent�(9.0�10�2T)(2)(1.60�10�19C)of6.0A,isatrightanglestoauniform(3.0�104m/s)magneticfield.Themagnitudeoftheforce�8.6�10�16Nactingonthewireis0.60N.WhatistheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.strengthofthemagneticfield?24.TriplyionizedparticlesinabeamcarryanetpositivechargeofthreeelementaryF�BILchargeunits.ThebeamentersamagneticF0.60NB�������0.13Tfieldof4.0�10�2T.TheparticleshaveaIL(6.0A)(0.75m)speedof9.0�106m/s.Whatisthemagni-tudeoftheforceactingoneachparticle?Physics:PrinciplesandProblemsSolutionsManual487
491Chapter24continuedF�Bqvloop,themagneticfieldoftheperma-�(4.0�10�2T)(3)(1.60�10�19C)nentmagnetexertsaforceontheloop.(9.0�106m/s)Theloopinagalvanometercannot�13Nrotatemorethan180°.Theloopinan�1.7�10electricmotorrotatesthroughmany360°turns.Themotor’ssplit-ringcom-25.Doublyionizedheliumatoms(alphaparti-mutatorallowsthecurrentinthelooptocles)aretravelingatrightanglestoamag-4m/s.Thereverseastheloopbecomesverticalinneticfieldataspeedof4.0�10fieldstrengthis5.0�10�2T.Whatforcethemagneticfield,enablingthelooptospininthemagneticfield.Thegal-actsoneachparticle?vanometermeasuresunknowncurrents;F�Bqvtheelectricmotorhasmanyuses.�(5.0�10�2T)(2)(1.60�10�19C)(4.0�104m/s)29.MotorsWhentheplaneofthecoilina�6.4�10�16Nmotorisperpendiculartothemagneticfield,theforcesdonotexertatorqueonthecoil.DoesthismeanthatthecoildoesnotSectionReviewrotate?Explain.Notnecessarily;ifthecoilisalreadyin24.2ForcesCausedbyrotation,thenrotationalinertiawillcarryMagneticFieldsitpastthepointofzerotorque.Itisthepages652–659coil’saccelerationthatiszero,notthepage659velocity.26.MagneticForcesImaginethatacurrent-carryingwireisperpendiculartoEarth’s30.ResistanceAgalvanometerrequires180�Amagneticfieldandrunseast-west.Ifthecur-forfull-scaledeflection.Whatisthetotalrentiseast,inwhichdirectionistheforceresistanceofthemeterandthemultiplieronthewire?resistorfora5.0-Vfull-scaledeflection?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.up,awayfromthesurfaceofEarthR���V�50V�28k�I180�A27.DeflectionAbeamofelectronsina31.CriticalThinkingHowdoyouknowthatcathode-raytubeapproachesthedeflectingtheforcesonparallelcurrent-carryingwiresmagnets.Thenorthpoleisatthetopofthearearesultofmagneticattractionbetweentube;thesouthpoleisonthebottom.Ifyouwires,andnotaresultofelectrostatics?arelookingatthetubefromthedirectionofHint:Considerwhatthechargesarelikewhenthephosphorscreen,inwhichdirectionaretheforceisattractive.Thenconsiderwhatthetheelectronsdeflected?forcesarewhenthreewirescarrycurrentsinthetotheleftsideofthescreensamedirection.Ifthecurrentsareinthesamedirection,28.GalvanometersComparethediagramofatheforceisattractive.IfitwereduetogalvanometerinFigure24-18onpage655electrostaticforces,thelikechargeswiththeelectricmotorinFigure24-20onwouldmaketheforcerepulsive.Threepage656.Howisthegalvanometersimilarwireswouldallattracteachother,whichtoanelectricmotor?Howaretheydifferent?couldneverhappeniftheforceswereBoththegalvanometerandtheelectricduetoelectrostaticcharges.motorusealoopofwirepositionedbetweenthepolesofapermanentmag-net.Whenacurrentpassesthroughthe488SolutionsManualPhysics:PrinciplesandProblems
492Chapter24continuedChapterAssessmentConceptMappingpage664NS32.Completethefollowingconceptmapusingthefollowing:right-handrule,F�qvB,andF�ILB.Forceresultingfromamagneticfield37.Drawthemagneticfieldbetweentwolikemagneticpolesandthenbetweentwounlikemagneticpoles.Showthedirectionsexertedonaofthefields.(24.1)current-carryingmovingchargewireNNhasahasahasamagnitudedirectionmagnitudeNSgivenbygivenbygivenby38.Ifyoubrokeamagnetintwo,wouldyouhaveisolatednorthandsouthpoles?F�ILBright-handF�qvBExplain.(24.1)ruleNo,newpoleswouldformoneachofthebrokenends.MasteringConcepts39.Describehowtousethefirstright-handrulepage664todeterminethedirectionofamagneticfield33.Statetheruleformagneticattractionandaroundastraightcurrent-carryingwire.(24.1)repulsion.(24.1)Graspthewirewiththerighthand,Likepolesrepeloneanother;oppositekeepingthumbpointinginthedirectionpolesattract.oftheconventionalcurrentthroughthewire.Fingerswillencirclethewireand34.Describehowatemporarymagnetdifferspointinthedirectionofthefield.fromapermanentmagnet.(24.1)Atemporarymagnetislikeamagnet40.Ifacurrent-carryingwireisbentintoaonlywhileundertheinfluenceofloop,whyisthemagneticfieldinsidetheanothermagnet.Apermanentmagnetloopstrongerthanthemagneticfieldout-needsnooutsideinfluence.side?(24.1)Themagneticfieldlinesareconcentrat-35.Namethethreemostimportantcommonedinsidetheloop.magneticelements.(24.1)iron,cobalt,andnickelCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.41.Describehowtousethesecondright-handruletodeterminethepolarityofanelectro-36.Drawasmallbarmagnetandshowthemagnet.(24.1)magneticfieldlinesastheyappeararoundthemagnet.Usearrowstoshowthedirec-tionofthefieldlines.(24.1)Physics:PrinciplesandProblemsSolutionsManual489
493Chapter24continuedGraspthecoilwiththerighthand,keep-Useacompass.Thenorthpoleoftheingthefingersencirclingthecoilinthecompassneedleisattractedtothesouthdirectionoftheconventionalcurrentpoleofthemagnetandviceversa.flowthroughtheloops.Thethumboftherighthandwillpointtowardthe48.Apieceofmetalisattractedtoonepoleofanorthpoleoftheelectromagnet.largemagnet.Describehowyoucouldtellwhetherthemetalisatemporarymagnetor42.Eachelectroninapieceofironislikeatinyapermanentmagnet.magnet.Theiron,however,maynotbeaMoveittotheotherpole.Ifthesamemagnet.Explain.(24.1)endisattracted,itisatemporaryTheelectronsarenotallorientedandmagnet;ifthesameendisrepelledandmovinginthesamedirection;theirtheotherendisattracted,itisaperma-magneticfieldshaverandomdirections.nentmagnet.43.Whywilldroppingorheatingamagnet49.IsthemagneticforcethatEarthexertsonaweakenit?(24.1)compassneedlelessthan,equalto,orThedomainsarejostledoutofalignment.greaterthantheforcethatthecompassneedleexertsonEarth?Explain.44.Describehowtousethethirdright-handTheforcesareequalaccordingtoruletodeterminethedirectionofforceonaNewton’sthirdlaw.current-carryingwireplacedinamagneticfield.(24.2)50.CompassSupposeyouarelostinthePointthefingersofyourrighthandinwoodsbuthaveacompasswithyou.thedirectionofthemagneticfield.PointUnfortunately,theredpaintmarkingtheyourthumbinthedirectionofthecon-northpoleofthecompassneedlehaswornventionalcurrentinthewire.Thepalmoff.Youhaveaflashlightwithabatteryandofyourhandthenfacesinthedirectionalengthofwire.Howcouldyouidentifyoftheforceonthewire.thenorthpoleofthecompass?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Connectthewiretothebatterysothatthe45.Astrongcurrentsuddenlyisswitchedoninacurrentisawayfromyouinonesection.wire.Noforceactsonthewire,however.CanHoldthecompassdirectlyaboveandyouconcludethatthereisnomagneticfieldclosetothatsectionofthewire.Bytheatthelocationofthewire?Explain.(24.2)right-handrule,theendofthecompassNo,ifafieldisparalleltothewire,noneedlethatpointsrightisthenorthpole.forcewouldresult.51.Amagnetcanattractapieceofironthatis46.Whatkindofmeteriscreatedwhenashuntnotapermanentmagnet.Achargedrubberisaddedtoagalvanometer?(24.2)rodcanattractanunchargedinsulator.Describethedifferentmicroscopicprocessesanammeterproducingthesesimilarphenomena.ApplyingConceptsThemagnetcausesthedomainsintheirontopointinthesamedirection.Thepages664–665chargedrodseparatesthepositiveand47.Asmallbarmagnetishiddeninafixednegativechargesintheinsulator.positioninsideatennisball.Describeanexperimentthatyoucoulddotofindthe52.Acurrent-carryingwirerunsacrossalabora-locationofthenorthpoleandthesouthtorybench.Describeatleasttwowaysinpoleofthemagnet.whichyoucouldfindthedirectionofthecurrent.490SolutionsManualPhysics:PrinciplesandProblems
494Chapter24continuedUseacompasstofindthedirectionofFacingthefrontoftheroom,thethemagneticfield.Bringupastrongvelocityisforward,theforceisupward,magnetandfindthedirectionoftheforceandtherefore,usingthethirdright-handonthewire,thenusetheright-handrule.rule,Bistotheleft.53.Inwhichdirection,inrelationtoamagnetic58.Earth’smagneticfieldlinesareshowninfield,wouldyourunacurrent-carryingwireFigure24-23.Atwhatlocation,polesorsothattheforceonit,resultingfromtheequator,isthemagneticfieldstrengthfield,isminimized,orevenmadetobezero?greatest?Explain.Runthewireparalleltothemagneticfield.MagneticpoleNorthpole54.Twowirescarryequalcurrentsandrunpar-alleltoeachother.Sa.Ifthetwocurrentsareinoppositedirec-tions,wherewillthemagneticfieldNfromthetwowiresbelargerthanthefieldfromeitherwirealone?Themagneticfieldwillbelargerany-SouthpoleMagneticpolewherebetweenthetwowires.■Figure24-23b.Wherewillthemagneticfieldfrombothbeexactlytwiceaslargeasfromonewire?Earth’smagneticfieldstrengthisgreatestatthepoles.ThefieldlinesareThemagneticfieldwillbetwiceasclosertogetheratthepoles.largealongalinedirectlybetweenthewiresthatisequalindistanceMasteringProblemsfromeachwire.24.1Magnets:PermanentandTemporaryc.Ifthetwocurrentsareinthesamedirec-pages665–666tion,wherewillthemagneticfieldbeexactlyzero?Level159.AsthemagnetbelowinFigure24-24Themagneticfieldwillbezeroalongmovestowardthesuspendedmagnet,whatalinedirectlybetweenthewiresthatwillthemagnetsuspendedbythestringdo?isequalindistancefromeachwire.55.Howistherangeofavoltmeterchangedwhentheresistor’sresistanceisincreased?SNNSTherangeofthevoltmeterincreases.56.Amagneticfieldcanexertaforceonachargedparticle.Canthefieldchangethe■Figure24-24particle’skineticenergy?Explain.Movetotheleftorbegintoturn.LikeNo,theforceisalwaysperpendicularpolesrepel.tothevelocity.Noworkisdone.Theenergyisnotchanged.60.AsthemagnetinFigure24-25movesCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.towardthesuspendedmagnet,whatwillthe57.Abeamofprotonsismovingfromthemagnetthatissuspendedbythestringdo?backtothefrontofaroom.Itisdeflectedupwardbyamagneticfield.Whatisthedirectionofthefieldcausingthedeflection?Physics:PrinciplesandProblemsSolutionsManual491
495Chapter24continued64.Aconventionalcurrentflowsthroughawire,asshowninFigure24-28.CopythewiresegmentandsketchthemagneticfieldSNSNthatthecurrentgenerates.I■Figure24-25Movetotheright.Unlikepolesattract.61.RefertoFigure24-26toanswerthefollow-ingquestions.■Figure24-281I423■Figure24-26a.Wherearethepoles?65.Thecurrentiscomingstraightoutofthe4and2,bydefinitionpageinFigure24-29.Copythefigureandb.Whereisthenorthpole?sketchthemagneticfieldthatthecurrentgenerates.2,bydefinitionandfielddirectionc.Whereisthesouthpole?4,bydefinitionandfielddirection62.Figure24-27showstheresponseofacompassCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.intwodifferentpositionsnearamagnet.■Figure24-29Whereisthesouthpoleofthemagnetlocated?■Figure24-27Attherightend,unlikepolesattract.66.Figure24-30showstheendviewofanelec-tromagnetwithcurrentflowingthroughit.63.Awirethatis1.50mlongandcarryingacurrentof10.0Aisatrightanglestoauni-formmagneticfield.Theforceactingonthewireis0.60N.Whatisthestrengthofthemagneticfield?F�ILBF0.60NIB�������0.040N/A�mIL(10.0A)(1.50m)�0.040T■Figure24-30492SolutionsManualPhysics:PrinciplesandProblems
496Chapter24continueda.Whatisthedirectionofthemagnetic24.2ForcesCausedbyMagneticFieldsfieldinsidetheloops?pages666–667downintothepageLevel1b.Whatisthedirectionofthemagnetic68.ThearrangementshowninFigure24-31isfieldoutsidetheloops?usedtoconvertagalvanometertowhattypeofdevice?up(outofthepage)Level267.CeramicMagnetsTherepulsiveforceGbetweentwoceramicmagnetswasmeasuredandfoundtodependondistance,asgiveninTable24-1.■Figure24-31Table24-1Ammeter,muchofthecurrentflowsthroughtheresistorandallowstheSeparation,d(cm)Force,F(N)measurementofhighercurrents.1.03.931.20.4069.WhatistheresistorshowninFigure24-31called?1.40.13Shunt;bydefinitionshuntisanother1.60.057wordforparallel.1.80.0302.00.01870.ThearrangementshowninFigure24-32isusedtoconvertagalvanometertowhat2.20.011typeofdevice?2.40.00762.60.00532.80.0038G3.00.0028a.Plottheforceasafunctionofdistance.■Figure24-32Voltmeter;theaddedresistance4.0decreasesthecurrentforanygivenvoltage.3.071.WhatistheresistorshowninFigure24-32(N)called?F2.0Multiplier;bydefinitionsinceitmulti-pliesthevoltagerangeofthemeter1.072.Acurrent-carryingwireisplacedbetweenthepolesofamagnet,asshowninFigure24-33.0.01.01.41.82.22.63.0Whatisthedirectionoftheforceonthewire?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.d(cm)b.Doesthisforcefollowaninversesquarelaw?No.Physics:PrinciplesandProblemsSolutionsManual493
497Chapter24continued77.Awirethatis625mlongisperpendicularIStoa0.40-Tmagneticfield.A1.8-Nforceactsonthewire.Whatcurrentisinthewire?NF�ILBF1.8NI������BL(0.40T)(625m)�0.0072A■Figure24-33�7.2mAIS78.Theforceona0.80-mwirethatisperpen-diculartoEarth’smagneticfieldis0.12N.NWhatisthecurrentinthewire?UseF5.0�10�5TforEarth’smagneticfield.F�ILBF0.12NI�������BL(5.0�10�5T)(0.80m)73.Awirethatis0.50mlongandcarryingacurrentof8.0Aisatrightanglestoauni-�3.0�103Aformmagneticfield.Theforceonthewire�3.0kAis0.40N.Whatisthestrengthofthemag-neticfield?79.Theforceactingonawirethatisatrightanglestoa0.80-Tmagneticfieldis3.6N.F�ILBThecurrentinthewireis7.5A.HowlongB��F�����0.40N0.10Tisthewire?IL(8.0A)(0.50m)F�ILB74.Thecurrentthroughawirethatis0.80mF3.6NL�������0.60mlongis5.0A.ThewireisperpendiculartoaBI(0.80T)(7.5A)0.60-Tmagneticfield.Whatisthemagni-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tudeoftheforceonthewire?Level2F�ILB�(5.0A)(0.80m)(0.60N/A�m)80.Apowerlinecarriesa225-Acurrentfromeasttowest,paralleltothesurfaceofEarth.�2.4Na.Whatisthemagnitudeoftheforce75.Awirethatis25cmlongisatrightanglesresultingfromEarth’smagneticfieldtoa0.30-Tuniformmagneticfield.Thecur-actingoneachmeterofthewire?Userentthroughthewireis6.0A.WhatistheB�5T.Earth�5.0�10magnitudeoftheforceonthewire?F�ILBF�ILB�(6.0A)(0.25m)(0.30N/A�m)�F��IB�(225A)(5.0�10�5T)�0.45NL�0.011N/m76.Awirethatis35cmlongisparalleltoa0.53-Tuniformmagneticfield.Thecurrentb.Whatisthedirectionoftheforce?throughthewireis4.5A.WhatforceactsTheforcewouldbedownward.onthewire?c.Inyourjudgment,wouldthisforcebeIfthewireisparalleltothefield,noimportantindesigningtowerstoholdcuttingistakingplace,sonoforceisthispowerline?Explain.produced.No;theforceismuchsmallerthantheweightofthewires.494SolutionsManualPhysics:PrinciplesandProblems
498Chapter24continued81.GalvanometerAgalvanometerdeflectsF�Bqvfull-scalefora50.0-�Acurrent.�(6.0�10�2T)(1.6�10�19C)a.Whatmustbethetotalresistanceofthe(2.5�106m/s)seriesresistorandthegalvanometerto�2.4�10�14Nmakeavoltmeterwith10.0-Vfull-scaledeflection?84.SubatomicParticleAmuon(aparticleV�IRwiththesamechargeasanelectron)istravelingat4.21�107m/satrightanglesV10.0V5�R�������2.00�10I50.0�10�6Atoamagneticfield.Themuonexperiences2k�aforceof5.00�10�12N.�2.00�10a.Howstrongisthemagneticfield?b.Ifthegalvanometerhasaresistanceof1.0k�,whatshouldbetheresistanceofF�qvBtheseries(multiplier)resistor?FB���Totalresistance�2.00�102k�,soqvtheseriesresistoris2.00�102k��5.00�10�12N�����1.0k��199k�.(1.60�10�19C)(4.21�107m/s)�0.742T82.Thegalvanometerinproblem81isusedtob.Whataccelerationdoesthemuonexpe-makeanammeterthatdeflectsfull-scaleforrienceifitsmassis1.88�10�28kg?10mA.F�maa.Whatisthepotentialdifferenceacrossthegalvanometer(1.0k�resistance)whenaF5.00�10�12Na�����m1.88�10�28kgcurrentof50�Apassesthroughit?V�IR�(50�10�6A)(1.0�103�)�2.66�1016m/s2�0.05V85.Asinglyionizedparticleexperiencesaforceb.Whatistheequivalentresistanceofpar-of4.1�10�13Nwhenittravelsatrightallelresistorshavingthepotentialdiffer-anglesthrougha0.61-Tmagneticfield.encecalculatedinacircuitwithatotalWhatisthevelocityoftheparticle?currentof10mA?F�qvBV�IRF4.1�10�13NV5�10�2Vv���Bq���(0.61T)(1.60�10�19C)R�������5�I0.01A6m/s�4.2�10c.Whatresistorshouldbeplacedparallelwiththegalvanometertomakethe86.Aroomcontainsastrong,uniformmagneticresistancecalculatedinpartb?field.Aloopoffinewireintheroomhas111currentflowingthroughit.Assumethatyou�����soRR1R2rotatetheloopuntilthereisnotendencyforittorotateasaresultofthefield.Whatisthe11111�����������R1RR25�1.0�103�directionofthemagneticfieldrelativetotheplaneofthecoil?soR1�5�ThemagneticfieldisperpendiculartoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.theplaneofthecoil.Theright-handrule83.Abeamofelectronsmovesatrightanglestoamagneticfieldof6.0�10�2T.Theelectronswouldbeusedtofindthedirectionofhaveavelocityof2.5�106m/s.Whatisthethefieldproducedbythecoil.Thefieldmagnitudeoftheforceoneachelectron?intheroomisinthesamedirection.Physics:PrinciplesandProblemsSolutionsManual495
499Chapter24continued87.Aforceof5.78�10�16Nactsonan(24V)(0.075m)(1.9T)����unknownparticletravelingata90°angle5.5�throughamagneticfield.Ifthevelocityof�0.62Ntheparticleis5.65�104m/sandthefieldisc.Determinetheforceonthewire(direc-3.20�10�2T,howmanyelementarytionandmagnitude)whentheswitchischargesdoestheparticlecarry?closedandthebatteryisreversed.F�qvBDown,0.62N.ThedirectionoftheF5.78�10�16Nforceisgivenbythethirdright-handq�������Bv(3.20�10�2T)(5.65�104m/s)ruleandthemagnitudeoftheforce�3.20�10�19Cisthesameasinpartb.1charged.Determinetheforceonthewire(direc-N�(3.20�10�19C)����tionandmagnitude)whentheswitchis1.60�10�19Cclosedandthewireisreplacedwithadif-�2chargesferentpiecehavingaresistanceof5.5�.MixedReviewUp,0.31N.Thedirectionoftheforceisgivenbythethirdright-handrule.pages667–668Level2I��VR88.AcopperwireofinsignificantresistanceisplacedinthecenterofanairgapF�ILB��VLBRbetweentwomagneticpoles,asshowninFigure24-34.Thefieldisconfined����(24V)(0.075m)(1.9T)5.5��5.5�tothegapandhasastrengthof1.9T.�0.31N5.5W7.5cmN89.Twogalvanometersareavailable.Onehas50.0-�Afull-scalesensitivityandtheotherShas500.0-�Afull-scalesensitivity.BothCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.havethesamecoilresistanceof855�.Yourchallengeistoconvertthemtomeasurea24Vcurrentof100.0mA,full-scale.a.Determinetheshuntresistorforthe50.0-�Ameter.■Figure24-34Findthevoltageacrossthemetera.Determinetheforceonthewire(direc-coilatfullscale.tionandmagnitude)whentheswitchisV�IR�(50.0�A)(855�)�0.0428Vopen.Calculatetheshuntresistor.0N.Withnocurrent,thereisnomag-neticfieldproducedbythewireandR���V���0.0428VI100.0mA�50.0�Acopperisnotamagneticmaterial.�0.428�b.Determinetheforceonthewire(direc-tionandmagnitude)whentheswitchisb.Determinetheshuntresistorfortheclosed.500.0-�Ameter.Up,0.62N.ThedirectionoftheforceFindthevoltageacrossthemeterisgivenbythethirdright-handrule.coilatfullscale.VV�IR�(500.0�A)(855�)�0.428VI��RVLBF�ILB��R496SolutionsManualPhysics:PrinciplesandProblems
500Chapter24continuedCalculatetheshuntresistor.L�(#ofturns)(circumference)�n�dV0.428VF�BILR������I100.0mA�500.0�ABVn�dF����4.30�Rc.Determinewhichofthetwoisbetterfor(0.15T)(15V)(250)(�)(0.025m)�����actualuse.Explain.8.0�The50.0-�Ameterisbetter.Its�5.5Nmuchlowershuntresistancewilldolesstoalterthetotalresistanceof94.Awirecarrying15Aofcurrenthasalengththecircuitbeingmeasured.Anidealof25cminamagneticfieldof0.85T.Theammeterhasaresistanceof0�.forceonacurrent-carryingwireinauni-formmagneticfieldcanbefoundusingthe90.SubatomicParticleAbetaparticle(high-equationF�ILBsin�.Findtheforceonspeedelectron)istravelingatrightanglestothewirewhenitmakesthefollowinganglesa0.60-Tmagneticfield.Ithasaspeedofwiththemagneticfieldlinesof2.5�107m/s.Whatsizeforceactsonthea.90°particle?F�ILBsin�F�Bqv�(15A)(0.25m)(0.85T)(sin90°)�(0.60T)(1.6�10�19C)(2.5�107m/s)�3.2N�2.4�10�12Nb.45°91.Themassofanelectronis9.11�10�31kg.F�ILBsin�Whatisthemagnitudeoftheaccelerationof�(15A)(0.25m)(0.85T)(sin45°)thebetaparticledescribedinproblem90?�2.3NF�mac.0°F2.4�10�12Na���m��9.11�10�31kgsin0°�0�2.6�1018m/s2soF�0N92.Amagneticfieldof16Tactsinadirection95.Anelectronisacceleratedfromrestthroughduewest.Anelectronistravelingduesouthapotentialdifferenceof20,000V,whichat8.1�105m/s.WhatarethemagnitudeexistsbetweenplatesP1andP2,showninandthedirectionoftheforceactingontheFigure24-35.Theelectronthenpasseselectron?throughasmallopeningintoamagneticfieldofuniformfieldstrength,B.Asindi-F�Bqvcated,themagneticfieldisdirectedinto�(16T)(1.6�10�19C)(8.1�105m/s)thepage.�2.1�10�12N,upward(right-handP1P2rule—rememberingthatelectronflowisXXXXXXXoppositetocurrentflow)XXXXXXXXXXXXXX93.LoudspeakerThemagneticfieldinaloud-ElectronXXXXXXXspeakeris0.15T.Thewireconsistsof250XXXXXXXturnswoundona2.5-cm-diametercylindri-XXXXXXXCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.calform.Theresistanceofthewireis8.0�.■Figure24-35Findtheforceexertedonthewirewhena.Statethedirectionoftheelectricfield15Visplacedacrossthewire.betweentheplatesaseitherP1toP2orVPI��2toP1.RfromP2toP1Physics:PrinciplesandProblemsSolutionsManual497
501Chapter24continuedb.Intermsoftheinformationgiven,cal-fieldthatis0.5mfromsuchawireculatetheelectron’sspeedatplatePcomparetoEarth’smagneticfield?2.KE�q�V�(1.6�10�19C)I�10A,d�0.5m,so(20,000J/C)(2�10�7T�m/A)IB����3.2�10�15Jd1(2�10�7T�m/A)(10A)KE��mv2����20.5m2KE(2)(3.2�10�15J)�4�10�6Tv�������m���9.11�10�31kgEarth’sfieldis5�10�5T,soEarth’s�8�107m/sfieldisabout12timesstrongerthanthatofthewire.c.Describethemotionoftheelectronthroughthemagneticfield.b.High-voltagepowertransmissionlinesoftencarry200Aatvoltagesashighasclockwise765kV.Estimatethemagneticfieldonthegroundundersuchaline,assumingThinkingCriticallythatitisabout20mhigh.Howdoespage668thisfieldcomparewithamagneticfield96.ApplyConceptsAcurrentissentthroughinyourhome?averticalspring,asshowninFigure24-36.I�200A,d�20m,soTheendofthespringisinacupfilledwithmercury.Whatwillhappen?Why?(2�10�7T�m/A)IB���d(2�10�7T�m/A)(200A)����Spring20m�2�10�6TThisishalfasstrongasthefieldinparta.MercuryCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.Someconsumergroupshaverecommend-edthatpregnantwomennotuseelectric■Figure24-36blanketsincasethemagneticfieldscausehealthproblems.EstimatethedistanceWhenthecurrentpassesthroughthethatafetusmightbefromsuchawire,coil,themagneticfieldincreasesandclearlystatingyourassumptions.Ifsuchaforcescausethespringtocompress.blanketcarries1A,findthemagneticfieldThewirecomesoutofthemercury,atthelocationofthefetus.Comparethisthecircuitopens,themagneticfieldwithEarth’smagneticfield.decreases,andthespringdropsdown.Thespringwilloscillateupanddown.Assumeonlyonewirerunsover“thefetus,andusethecenterofthe97.ApplyConceptsThemagneticfieldpro-fetus(wherethevitalorgansare)asducedbyalong,current-carryingwireisareferencepoint.Atanearlystage,representedbyB�(2�10�7T�m/A)(I/d),thefetusmightbe5cmfromthewhereBisthefieldstrengthinteslas,Iisblanket.Atlaterstages,thecenterthecurrentinamps,anddisthedistanceofthefetusmaybe10cmaway.fromthewireinmeters.UsethisequationI�1A,d�0.05m,sotoestimatesomemagneticfieldsthatyou(2�10�7T�m/A)Iencounterineverydaylife.B���da.Thewiringinyourhomeseldomcarries(2�10�7T�m/A)(1A)����morethan10A.Howdoesthemagnetic0.05m498SolutionsManualPhysics:PrinciplesandProblems
502Chapter24continued�4�10�6TStudentanswersmayvary.Super-Earth’smagneticfieldof5�10�5Tisconductingmagnetscurrentlyareusedinmagneticresonanceimaging(MRI),aabout12timesstronger.medicaltechnology.Theyarebeingtest-98.AddVectorsInalmostallcasesdescribededforuseinmagneticallylevitatedhigh-inproblem97,asecondwirecarriesthespeedtrains,anditishopedthatsuper-samecurrentintheoppositedirection.Findconductingmagnetswillhelptomakethenetmagneticfieldthatisadistanceofnuclearfusionenergypractical.Adraw-0.10mfromeachwirecarrying10A.Thebackofsuperconductingmagnetsisthatwiresare0.01mapart.Makeascaledraw-theyrequireextremelylowtemperaturesingofthesituation.Calculatethemagni-(nearabsolutezero).Scientistsaretry-tudeofthefieldfromeachwireanduseaingtodevelopmaterialsthataresuper-right-handruletodrawvectorsshowingtheconductiveathighertemperatures.directionsofthefields.Finally,findthevec-torsumofthetwofields.Stateitsmagni-CumulativeReviewtudeanddirection.page668100.HowmuchworkisrequiredtomoveaB1chargeof6.40�10�3Cthroughapoten-�tialdifferenceof2500V?(Chapter21)BW�qV�(6.40�10�3C)(2500V)�16JBIin�WireB0.10m101.Thecurrentflowina120-Vcircuitincreas-0.005m0.005mesfrom1.3Ato2.3A.Calculatethe0.10m�WireAchangeinpower.(Chapter22)IoutBAP�IVP1�I1V,P2�I2V��P�P2�P1�I2V�I1VB1�V(I2�I1)FromeachwireI�10A,d�0.10m,so�(120V)(2.3A�1.3A)(2�10�7T�m/A)(10A)�5TB�����2�10�120W0.10mFromthediagram,onlythecomponents102.Determinethetotalresistanceofthree,paralleltothelinefromthecenterof55-�resistorsconnectedinparallelandthewirescontributetothenetfieldthenseries-connectedtotwo55-�resistorsstrength.Thecomponentfromeachconnectedinseries.(Chapter23)wireisB1�Bsin�,wheresin���0.00�5m�0.05,soB�5T)�1�����1�1�1�1��0.10m1�(2�10RparallelRRR55�(0.05)�1�10�6T.But,eachwirecon-113tributesthesameamount,sothetotal�������55�55�55�fieldis2�10�6T,about1/25Earth’sfield.Rparallel�18�WritingInPhysicsRequiv�Rparallel�R�RCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page668�18��55��55�99.Researchsuperconductingmagnetsandwrite�128�aone-pagesummaryofproposedfutureusesforsuchmagnets.Besuretodescribeanyhurdlesthatstandinthewayofthepracticalapplicationofthesemagnets.Physics:PrinciplesandProblemsSolutionsManual499
503Chapter24continuedSimplifyingandreplacing(depth)(width)ChallengeProblemwitharea,A,gives:page656��nBIAThefigureshowstwoidenticalmotorswithaThetorqueproducedbythemotorcommonshaft.Forsimplicity,thecommutatorsarmature,inthepositionshown,isarenotshown.Eacharmaturecoilconsistsofequaltothenumberofturnstimesthe48turnsofwirewithrectangulardimensionsoffieldstrengthtimesthearmaturecur-17cmwideby35cmdeep.Thearmaturerenttimestheareaofthearmaturecoil.resistanceis12�.Theredwiretravelstotheleft(alonghalfthewidth)andthenbacktotherear2.WithS1closedandS2open,determinetheofthemotor(alongthedepth).Themagnetictorqueontheshaftandtheforceonthefieldis0.21T.Thediameterofthepulleyisspringscale.7.2cm.Aropefixedtothepulleyandthefloor��nBIApreventsthemotorshaftfromturning.120V�(48)(0.21T)����(0.35m)(0.17m)12�S�6.0N�mNBecausetheshaftcannotturn,thesys-temisinequilibriumandtheforceonShaftSthespringscaleisfoundbyconsider-S2inghalfthepulleydiameter:N6.0N�m35VFspringscale��0.03�6m�170NPulleyS13.Withbothswitchesclosed,determinethetorqueontheshaftandtheforceontheSpringspringscale.120VscaleBothmotorsproducecounterclockwiseCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.torque:1.GivenF�ILB,deriveanequationforthe120Vtorqueonthearmaturefortheposition�1�(48)(0.21T)��12���(0.35m)(0.17m)shown.�6.0N�mTorqueisdefinedastheproductofthe35Vforceandtheleverarm.Inthecaseof�2�(48)(0.21T)��12���(0.35m)(0.17m)themotorarmaturepositionshown,the�1.7N�mleverarmisequaltohalfofthewidthof�thearmaturecoil(theshaftisthecenternet�7.7N�mcounterclockwiseofrotationandisatthemidpointofthe7.7N�mF���210Nspringscale�0.036mcoilwidth).Thelengthofthewireacteduponbythefieldisequaltothedepth4.Whathappenstotorqueifthearmatureisofthecoil.Thislengthiseffectivelyinadifferentposition?increasedbyn,thenumberofturnsinThetorqueisreducedwhenthereisthecoil.Finally,thetorqueisdoubledanyrotationfromthepositionshownbecauseasonesideispushedupbybecausetheleverarmisreduced.Withthemagneticfield,theothersideis90°rotation,theforceonthearmaturepusheddownaccordingtothethirdwillbeupanddown(canceling)withright-handrule.theeffectiveleverarmequaltozero.��2nBI(depth)(width/2)Withtheshownpositionas��0°:��nBIAcos�500SolutionsManualPhysics:PrinciplesandProblems
504CHAPTER25ElectromagneticInduction4.ApermanenthorseshoemagnetismountedPracticeProblemssothatthemagneticfieldlinesarevertical.If25.1ElectricCurrentfromastudentpassesastraightwirebetweentheChangingMagneticFieldspolesandpullsittowardherself,thecurrentflowthroughthewireisfromrighttoleft.pages671–678Whichisthenorthpoleofthemagnet?page675Usingtheright-handrule,thenorth1.Astraightwire,0.5mlong,ismovedpoleisatthebottom.straightupataspeedof20m/sthrougha0.4-Tmagneticfieldpointedinthehorizontaldirection.page678a.WhatEMFisinducedinthewire?5.AgeneratordevelopsamaximumvoltageEMF�BLvof170V.�(0.4T)(0.5m)(20m/s)a.Whatistheeffectivevoltage?�4VVeff�(0.707)Vmax�(0.707)(170V)b.Thewireispartofacircuitoftotal�1.2�102Vresistanceof6.0�.Whatisthecurrentb.A60-Wlightbulbisplacedacrossinthecircuit?thegeneratorwithanImaxof0.70A.EMF4VWhatistheeffectivecurrentthroughI�������0.7AR6.0�thebulb?2.Astraightwire,25mlong,ismountedonIeff�(0.707)Imax�(0.707)(0.70A)anairplaneflyingat125m/s.Thewire�0.49AmovesinaperpendiculardirectionthroughEarth’smagneticfield(B�5.0�10�5T).c.Whatistheresistanceofthelightbulbwhenitisworking?WhatEMFisinducedinthewire?VEMF�BLv�ma�x�5T)(25m)(125m/s)Veff�2�Vmax170V�(5.0�10R�����������IeffImaxImax0.70A���0.16V�2��2.4�102�3.Astraightwire,30.0mlong,movesat2.0m/sinaperpendiculardirection6.TheRMSvoltageofanAChouseholdoutletthrougha1.0-Tmagneticfield.is117V.Whatisthemaximumvoltagea.WhatEMFisinducedinthewire?acrossalampconnectedtotheoutlet?IfEMF�BLvtheRMScurrentthroughthelampis5.5A,�(1.0T)(30.0m)(2.0m/s)whatisthemaximumcurrentinthelamp?�6.0�101VVeff117VV�����165Vmax�0.7070.707Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.ThetotalresistanceofthecircuitofIwhichthewireisapartis15.0�.WhatI�ef�f��5.5A�7.8Amax�0.7070.707isthecurrent?EMF6.0�101V7.AnACgeneratordeliversapeakvoltageofI�������4.0AR1.50�425V.Physics:PrinciplesandProblemsSolutionsManual501
505Chapter25continueda.WhatistheVwhenthemagneticfieldismadestronger.effinacircuitplacedacrossthegenerator?WhatelseisaffectedbystrengtheningtheVmax425Vmagneticfield?V��2Veff���3.01�10Themagnitudeoftheinducedvoltageis�2��2�directlyrelatedtothestrengthoftheb.Theresistanceis5.0�102�.Whatisthemagneticfield.Agreatervoltageiseffectivecurrent?inducedintheconductor(s)ifthefieldVeff3.01�102Vstrengthisincreased.ThecurrentandI���eff�R�5.0�102��0.60Athepowerinthegeneratorcircuitalso8.Iftheaveragepowerdissipatedbyanelectricwereaffected.lightis75W,whatisthepeakpower?14.GeneratorExplainthefundamental1P���Poperatingprincipleofanelectricgenerator.2maxMichaelFaradaydiscoveredthatavolt-P2Wmax�(2)P�(2)(75W)�1.5�10ageisinducedinalengthofelectricwiremovinginamagneticfield.TheinducedvoltagemaybeincreasedbyusingaSectionReviewstrongermagneticfield,increasingthe25.1ElectricCurrentfromvelocityoftheconductor,orincreasingChangingMagneticFieldstheeffectivelengthoftheconductor.pages671–67815.CriticalThinkingAstudentasks,“Whypage678doesACdissipateanypower?Theenergy9.GeneratorCouldyoumakeageneratorbygoingintothelampwhenthecurrentismountingpermanentmagnetsonarotatingpositiveisremovedwhenthecurrentisshaftandkeepingthecoilstationary?negative.Thenetiszero.”ExplainwhythisExplain.reasoningiswrong.Yes,onlyrelativemotionbetweenthePoweristherateatwhichenergyisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.coilandthemagneticfieldisimportant.transferred.PoweristheproductofIandV.WhenIispositive,soisVand10.BikeGeneratorAbikegeneratorlightsthetherefore,Pispositive.WhenIisnega-headlamp.Whatisthesourceoftheenergytive,soisV;thus,Pispositiveagain.forthebulbwhentheridertravelsalongaEnergyisalwaystransferredinthelamp.flatroad?thestoredchemicalenergyofthebikeriderPracticeProblems11.MicrophoneConsiderthemicrophone25.2ChangingMagneticshowninFigure25-3.WhenthediaphragmFieldsInduceEMFispushedin,whatisthedirectionofthepages679–685currentinthecoil?page684clockwisefromtheleftForthefollowingproblems,effectivecurrentsandvoltagesareindicated.12.FrequencyWhatchangestothegenerator16.Astep-downtransformerhas7500turnsarerequiredtoincreasethefrequency?onitsprimarycoiland125turnsonitsincreasethenumberofmagneticpolesecondarycoil.Thevoltageacrossthepri-pairsmarycircuitis7.2kV.Whatvoltageisbeingappliedacrossthesecondarycircuit?Ifthe13.OutputVoltageExplainwhytheoutputcurrentinthesecondarycircuitis36A,voltageofanelectricgeneratorincreases502SolutionsManualPhysics:PrinciplesandProblems
506Chapter25continuedwhatisthecurrentintheprimarycircuit?19.MotorsIfyouunpluggedarunningvacu-umcleanerfromawalloutlet,youwouldVN��s���sbemuchmorelikelytoseeasparkthanVNppyouwouldbeifyouunpluggedalightedVpNs(7.2�103V)(125)lampfromthewall.Why?V������s�N7500pTheinductanceofthemotorcreatesa2Vback-EMFthatcausesthespark.The�1.2�10bulbhasverylowself-inductance,soVpIp�VsIsthereisnoback-EMF.VsIs(1.2�102V)(36A)Ip��V�����7.2�103V�0.60A20.TransformersandCurrentExplainwhyaptransformermayonlybeoperatedonalter-17.Astep-uptransformerhas300turnsonnatingcurrent.itsprimarycoiland90,000turnsonitsInordertomagneticallylinkthesecondarycoil.TheEMFofthegeneratorprimaryandsecondarycoils,avaryingtowhichtheprimarycircuitisattachediscurrentmustflowintheprimarycoil.60.0V.WhatistheEMFinthesecondaryThischangingcurrentsetsupamag-circuit?Thecurrentinthesecondarycircuitisneticfieldthatbuilds,expandingout-0.50A.Whatcurrentisintheprimarycircuit?wards,andcollapsesasthecurrentVpNs(60.0V)(90,000)flowdirectionchanges.V�����s�N300p21.TransformersFrequently,transformercoils�1.80�104VthathaveonlyafewturnsaremadeofveryVI4V)(0.50A)thick(low-resistance)wire,whilethosewithss(1.80�10I������p�V60.0Vmanyturnsaremadeofthinwire.Why?pMorecurrentflowsthroughthecoilwith�1.5�102Afewerturns,sotheresistancemustbekeptlowtopreventvoltagedropsandI2Rpowerlossandheating.SectionReview22.Step-UpTransformersRefertothestep-up25.2ChangingMagnetictransformershowninFigure25-13.ExplainFieldsInduceEMFwhatwillhappentotheprimarycurrentifpages679–685thesecondarycoilisshort-circuited.page685Accordingtothetransformerequations,18.CoiledWireandMagnetsYouhangacoiltheratioofprimarytosecondarycur-ofwirewithitsendsjoinedsothatitcanrentisequaltotheratioofturnsandswingeasily.Ifyounowplungeamagnetdoesn’tchange.Thus,ifthesecondaryintothecoil,thecoilwillswing.Whichwaycurrentincreases,sodoestheprimary.willitswingrelativetothemagnetandwhy?23.CriticalThinkingWouldpermanentmag-Awayfromthemagnet.Thechangingnetsmakegoodtransformercores?Explain.magneticfieldinducesacurrentintheNo,theinducedvoltagedependsoncoil,producingamagneticfield.ThisachangingmagneticfieldthroughCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.fieldopposesthefieldofthemagnet,thecore.Permanentmagnetsareandthus,theforcebetweencoiland“permanent”becausetheyaremadeofmagnetisrepulsive.materialsthatresistsuchchangesinmagneticfields.Physics:PrinciplesandProblemsSolutionsManual503
507Chapter25continued28.WhatisthepolarityofthevoltageinducedChapterAssessmentinthewirewhenitpassesthesouthpoleofConceptMappingthemagneticfield?(25.1)page690Aconductormovingbyasouthmag-24.Completethefollowingconceptmapusingneticpolewillhaveapositiveinducedthefollowingterms:generator,back-EMF,voltage.Lenz’slaw.29.Whatistheeffectofincreasingthenetcon-ductorlengthinanelectricgenerator?(25.1)generatormotorIncreasingtheconductorlengthresultsinanetincreaseininducedvoltage.BoutofpageEMFback-EMFMichaelFaradayLenz’slawWireMasteringConcepts■ Figure25-16page69025.Whatisthearmatureofanelectric30.HowwereOersted’sandFaraday’sresultsgenerator?(25.1)similar?Howweretheydifferent?(25.1)ThearmatureofanelectricgeneratorTheyaresimilarinthattheyeachshowaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.consistsofanumberofwireloopsrelationshipbetweenelectricityandmag-woundaroundanironcoreandplacednetism.Theyaredifferentinthatasteadyinastrongmagneticfield.Asitrotateselectriccurrentproducesamagneticinthemagneticfield,theloopscutfield,butachangeinmagneticfieldisthroughmagneticfieldlinesandanneededtoproduceanelectriccurrent.electriccurrentisinduced.31.Youhaveacoilofwireandabarmagnet.26.Whyisironusedinanarmature?(25.1)Describehowyoucouldusethemtogener-Ironisusedinanarmaturetoincreaseateanelectriccurrent.(25.1)thestrengthofthemagneticfield.Eithermovethemagnetintooroutofthecoil,ormovethecoilupanddownForproblems27–29,refertoFigure25-16.overtheendofthemagnet.27.Asingleconductormovesthroughamag-neticfieldandgeneratesavoltage.Inwhat32.WhatdoesEMFstandfor?Whyisthenamedirectionshouldthewirebemoved,relativeinaccurate?(25.1)tothemagneticfieldtogeneratethemini-Electromotiveforce;itisnotaforcebutmumvoltage?(25.1)anelectricpotential(energyperunitofTheminimumamountofvoltage(0V),ischarge).generatedwhentheconductorismovingparalleltothemagneticlinesofforce.33.Whatisthedifferencebetweenageneratorandamotor?(25.1)504SolutionsManualPhysics:PrinciplesandProblems
508Chapter25continuedInagenerator,mechanicalenergyturnsThisisLenz’slaw.Oncethemotorstartsanarmatureinamagneticfield.Theturning,itbehavesasageneratorandinducedvoltageproducescurrent,thuswillgeneratecurrentinoppositiontotheproducingelectricenergy.Inamotor,currentbeingputintothemotor.voltageisplacedacrossanarmaturecoilinamagneticfield.Thevoltageproduces39.Whyistherenosparkwhenyoucloseacurrentinthecoilandthearmatureswitchandputcurrentthroughaninductor,turns,producingmechanicalenergy.butthereisasparkwhenyouopentheswitch?(25.2)34.ListthemajorpartsofanACgenerator.(25.1)Thesparkisfromtheback-EMFthatAnACgeneratorconsistsofaperma-triestokeepthecurrentflowing.Thenentmagnet,anarmature,asetofback-EMFislargebecausethecurrentbrushes,andaslipring.hasdroppedquicklytozero.Whenclos-ingtheswitch,thecurrentincreaseisn’t35.WhyistheeffectivevalueofanACcurrentsofastbecauseoftheresistanceinthelessthanitsmaximumvalue?(25.1)wires.Inanalternating-currentgenerator,asthearmatureturns,thegenerated40.Whyistheself-inductanceofacoilamajorpowervariesbetweensomemaximumfactorwhenthecoilisinanACcircuitbutavalueandzero.TheaveragepowerisminorfactorwhenthecoilisinaDCcircuit?equaltoone-halfthemaximumpower.(25.2)TheeffectivecurrentistheconstantAnalternatingcurrentisalwayschang-valueofcurrentthatwouldcausetheinginthemagnitudeanddirection.averagepowertobedissipatedintheTherefore,self-inductionisaconstantload,R.factor.AdirectcurrenteventuallyP�1�P�1�I2R�I2Rbecomessteady,andthus,afterashortavg�2max�2maxefftime,thereisnochangingmagneticfield.II�ma�x�I41.Explainwhythewordchangeappearssoeff�max�2�ofteninthischapter.(25.2)36.HydroelectricityWatertrappedbehindaAsFaradaydiscovered,onlyachangingdamturnsturbinesthatrotategenerators.magneticfieldinducesEMF.Listalltheformsofenergythattakepartinthecyclethatincludesthestoredwaterand42.UponwhatdoestheratiooftheEMFinthetheelectricityproduced.(25.1)primarycircuitofatransformertotheEMFThereispotentialenergyinthestoredinthesecondarycircuitofthetransformerwater,kineticenergyinthefallingwaterdepend?(25.2)andturningturbine,andelectricenergyTheratioofnumberofturnsofwireininthegenerator.Inaddition,therearetheprimarycoiltothenumberofturnsfrictionallossesintheturbineandgen-ofwireinthesecondarycoildetermineseratorresultinginthermalenergy.theEMFratio.37.StateLenz’slaw.(25.2)ApplyingConceptsAninducedcurrentalwaysactsinsuchaCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.pages690–692directionthatitsmagneticfieldopposes43.UseunitsubstitutiontoshowthattheunitsthechangebywhichthecurrentisofBLvarevolts.induced.TheunitofBLvis(T)(m)(m/s).38.Whatcausesback-EMFinanelectricmotor?T�N/A�mandA�C/s.(25.2)So,BLv�(N�s/C�m)(m)(m/s)�N�m/CPhysics:PrinciplesandProblemsSolutionsManual505
509Chapter25continuedBecauseJ�N�mandV�J/C,theunitofBLvisV(volts).44.Whenawireismovedthroughamagneticfield,doestheresistanceoftheclosedcircuitaffectcurrentonly,EMFonly,both,orneither?currentonly■ Figure25-1845.BikingAsLoganslowshisbike,whatItislargerseveraltenthsofasecondhappenstotheEMFproducedbyhisbike’saftertheconnectionismade.Theback-generator?UsethetermarmatureinyourEMFopposescurrentjustafterthecon-explanation.nectionismade.AsLoganslowshisbike,therotationofthearmatureinthemagneticfieldofthe49.Asegmentofawireloopismovinggeneratorslows,andtheEMFisreduced.downwardthroughthepolesofamagnet,asshowninFigure25-19.Whatisthe46.ThedirectionofACvoltagechangesdirectionoftheinducedcurrent?120timeseachsecond.DoesthismeanthatadeviceconnectedtoanACvoltagealter-Nnatelydeliversandacceptsenergy?SNo;thesignsofthecurrentandvoltagereverseatthesametime,and,therefore,vtheproductofthecurrentandthevolt-■ Figure25-19ageisalwayspositive.Thecurrentdirectionisout-of-pageto47.Awireismovedhorizontallybetweenthetheleftalongthepathofthewire.polesofamagnet,asshowninFigure25-17.Whatisthedirectionoftheinducedcurrent?50.AtransformerisconnectedtoabatteryCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.throughaswitch.Thesecondarycircuitcon-tainsalightbulb,asshowninFigure25-20.SNWillthelampbelightedaslongastheswitchisclosed,onlyatthemomenttheswitchisclosed,oronlyatthemomenttheswitchisopened?Explain.■ Figure25-17Nocurrentisinducedbecausethedirectionofthevelocityisparalleltothemagneticfield.PrimarySecondary48.Youmakeanelectromagnetbywindingwirearoundalargenail,asshownin■ Figure25-20Figure25-18.IfyouconnectthemagnettoThebulbwilllightbecausethereisaabattery,isthecurrentlargerjustafteryoucurrentinthesecondarycircuit.Thismaketheconnectionorseveraltenthsofawillhappenwhenevertheprimarycur-secondaftertheconnectionismade?Or,isrentchanges,sothebulbwillglowitalwaysthesame?Explain.eitherwhentheswitchisclosedorwhenitisopened.506SolutionsManualPhysics:PrinciplesandProblems
510Chapter25continued51.Earth’sMagneticFieldThedirectionofa.WhatisthedirectionofthecurrentEarth’smagneticfieldinthenorthernhemi-inducedinthepipebythefallingmagnetsphereisdownwardandtothenorthasifthesouthpoleistowardthebottom?showninFigure25-21.Ifaneast-westwireInducedEMFisperpendiculartobothmovesfromnorthtosouth,inwhichdirec-thefieldandvelocity,sothecurrenttionisthecurrent?mustbecircumferential.FieldlinesNorthmagneticpoleNorthpolemoveintowardthesouthpoleandoutfromthenorthpole.Bytheright-handrule,currentisclockwisenearSthesouthpoleandcounterclockwisenearthenorthpole.b.TheinducedcurrentproducesamagneticNfield.Whatisthedirectionofthefield?Nearthesouthpole,thefieldinsideSouthpoleSouthmagneticpolethepipeisdown;nearthenorthpole,■ Figure25-21itisup.Thecurrentisfromwesttoeast.c.Howdoesthisfieldreducetheaccelerationofthefallingmagnet?52.YoumovealengthofcopperwiredownInducedfieldexertsanupwardforcethroughamagneticfield,B,asshowninonbothpoles.Figure25-19.a.Willtheinducedcurrentmovetothe54.GeneratorsWhyisageneratormorediffi-rightorleftinthewiresegmentintheculttorotatewhenitisconnectedtoacir-diagram?cuitandsupplyingcurrentthanitiswhenitTheright-handrulewillshowtheisstandingalone?currentmovingleft.Whenthearmatureofageneratorisb.Assoonasthewireismovedintherotated,aforcethatopposesthedirec-field,acurrentappearsinit.Thus,thetionofrotationisproducedasaresultwiresegmentisacurrent-carryingwireofinducedcurrent(Lenz’slaw).Whenlocatedinamagneticfield.Aforcemuststandingalone,however,nocurrentisactonthewire.Whatwillbethedirec-generatedandconsequentlynooppos-tionoftheforceactingonthewireasaingforceisproduced.resultoftheinducedcurrent?55.Explainwhytheinitialstart-upcurrentissoTheforcewillactinanupwardhighinanelectricmotor.Alsoexplainhowdirection.Lenz’slawappliesattheinstantt�0.53.AphysicsinstructordropsamagnetIfthearmature(conductors)arenotthroughacopperpipe,asillustratedinrotating,nolinesofforcearebeingcut,Figure25-22.Themagnetfallsveryslowly,andnovoltageisinduced.Therefore,andthestudentsintheclassconcludethattheback-EMFiszero.Sincethereisnotheremustbesomeforceopposinggravity.currentinthearmature,nomagneticfieldisformedaroundthestationaryconductor.ItshouldbenotedthatthisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Nexplanationonlyholdstrueattheinstantofstartup,attimejustgreaterSthan0.Theinstantthearmaturebeginstorotate,itwillbecuttingthelinesofforceandwillhaveaninducedvoltage.■ Figure25-22Thisvoltage,theback-EMF,willhaveaPhysics:PrinciplesandProblemsSolutionsManual507
511Chapter25continuedpolaritysuchthatitproducesamagnetic59.Shawndropsamagnet,northpoledown,fieldopposingthefieldthatcreatedit.throughaverticalcopperpipe.Thisreducesthecurrentinthemotor.a.WhatisthedirectionoftheinducedTherefore,themotionofthemotorcurrentinthecopperpipeasthebot-increasesitsapparentresistance.tomofthemagnetpasses?clockwisearoundthepipe,as56.UsingFigure25-10inconjunctionwithviewedfromaboveLenz’slaw,explainwhyallpracticaltrans-formercoresincorporatealaminatedcore.b.Theinducedcurrentproducesamagnet-icfield.WhatisthedirectionoftheAlaminatedcoreisconstructedfrominducedmagneticfield?thinsheetsofsteel,separatedbyaverythincoatingofvarnish(insulation).downthepipe,atthelocationoftheEddycurrentsaregreatlyreducedsouthpoleofthemagnet(oroppo-becauseofthisinsulation.Currentinsitethemagnet’sfield)thecoreiscausedbythechangingmagneticfluxwithinthecore.TheeddyMasteringProblemscurrentsexistduetotheinducedvolt-25.1ElectricCurrentfromChangingagewithinthemagneticcore.MagneticFieldspages692–69357.ApracticaltransformerisconstructedwithaLevel1laminatedcorethatisnotasuperconductor.60.Awire,20.0-mlong,movesat4.0m/sper-Becausetheeddycurrentscannotbecom-pendicularlythroughamagneticfield.Anpletelyeliminated,thereisalwaysasmallEMFof40Visinducedinthewire.Whatiscoreloss.Thisresults,inpart,inanetlossthestrengthofthemagneticfield?ofpowerwithinthetransformer.Whatfun-EMF�BLvdamentallawmakesitimpossibletobringthislosstozero?EMF40VB�������Lv(20.0m)(4.0m/s)Lenz’slawCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.5T58.Explaintheprocessofmutualinductionwithinatransformer.61.AirplanesAnairplanetravelingat9.50�102km/hpassesoveraregionwhereAnACcurrentappliedtotheprimarycoilEarth’smagneticfieldis4.5�10�5Tandofatransformer,resultsinachangingisnearlyvertical.Whatvoltageisinducedcurrentflowthroughthecoilwinding.betweentheplane’swingtips,whichareThiscurrent,inturn,generatesamagnet-75mapart?icflux,alternatelybuildingandcollapsingasthedirectionofcurrentchanges.ThisEMF�BLvstrongmagneticfieldradiatesoutwardin�(4.5�10�5T)(75m)alldirectionsfromtheprimarycoil.When(9.50�102km/h)(1000m/km)themagneticfieldreachesthestationary(1h/3600s)secondarycoilontheothersideofthecore,avoltageisinducedwithinthatcoil.�0.89VThevoltageorEMFinduceddepends62.Astraightwire,0.75-mlong,movesupwardupontherateatwhichthemagneticfieldthroughahorizontal0.30-Tmagneticfield,alternates(supplyfrequency),numberofasshowninFigure25-23,ataspeedofturnsonthecoil,andthestrengthofthe16m/s.magneticflux.Sincethemagneticfluxisresponsibleforinducingavoltageina.WhatEMFisinducedinthewire?thesecondarycoil,wesaythatitisEMF�BLvmagneticallylinked.508SolutionsManualPhysics:PrinciplesandProblems
512Chapter25continued�(0.30T)(0.75m)(16m/s)66.ElectricStoveAnelectricstoveisconnected�3.6VtoanACsourcewithaneffectivevoltageof240V.b.Thewireispartofacircuitwithatotalresistanceof11W.Whatisthecurrent?a.Findthemaximumvoltageacrossoneofthestove’selementswhenitisoperating.EMF�IRVEMF3.6Veff�(0.707)VmaxI������0.33AR11�Veff240VV������340Vmax�0.7070.707Nb.TheresistanceoftheoperatingelementSis11�.Whatistheeffectivecurrent?Veff�IeffRvV■Figure25-23eff240VI��eff�R�11��22A63.Atwhatspeedwoulda0.20-mlengthofwirehavetomoveacrossa2.5-Tmagnetic67.YouwishtogenerateanEMFof4.5VbyfieldtoinduceanEMFof10V?movingawireat4.0m/sthrougha0.050-TEMF�BLvmagneticfield.Howlongmustthewirebe,andwhatshouldbetheanglebetweentheEMF10Vv������fieldanddirectionofmotiontousetheBL(2.5T)(0.20m)shortestwire?�20m/sEMF�BLv64.AnACgeneratordevelopsamaximumEMFEMF4.5VL������of565V.WhateffectiveEMFdoestheBv(0.050T)(4.0m/s)generatordelivertoanexternalcircuit?�23m�Vma�x��565V4.00�102VThisistheshortestlengthofwireassum-V�eff�ingthatthewireandthedirectionof�2��2�motionareeachperpendiculartothefield.65.AnACgeneratordevelopsamaximumvoltageof150V.ItdeliversamaximumLevel2currentof30.0Atoanexternalcircuit.68.A40.0-cmwireismovedperpendicularlythroughamagneticfieldof0.32Twithaa.Whatistheeffectivevoltageofthevelocityof1.3m/s.Ifthiswireisconnectedgenerator?intoacircuitof10.0-�resistance,whatisVeff�(0.707)Vmax�(0.707)(150V)thecurrent?�110VEMF�BLvb.Whateffectivecurrentdoesthegenerator�(0.32T)(0.400m)(1.3m/s)delivertotheexternalcircuit?�0.17VIeff�(0.707)Imax�(0.707)(30.0V)EMF0.17VI�������17mAR10.0��21.2Ac.Whatistheeffectivepowerdissipatedin69.YouconnectbothendsofacopperwirewithCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thecircuit?atotalresistanceof0.10�totheterminalsofIVagalvanometer.Thegalvanometerhasaresis-P�ma�x���ma�x�eff�IeffVeff��tanceof875�.Youthenmovea10.0-cm�2��2�segmentofthewireupwardat1.0m/s��1�I�1��througha2.0�10�2-Tmagneticfield.What2maxVmax��2(150V)(30.0A)currentwillthegalvanometerindicate?�2.3kWPhysics:PrinciplesandProblemsSolutionsManual509
513Chapter25continuedEMF�BLvPE4.4�108Jm��������2T)(0.100m)(1.0m/s)gh(9.80m/s2)(22m)�(2.0�10�3V�2.0�106kg�2.0�10V2.0�10�3V�6A72.AconductorrotatinginamagneticfieldhasI�������2.3�10R875�alengthof20cm.Ifthemagnetic-fluxden-�2.3�Asityis4.0T,determinetheinducedvoltagewhentheconductorismovingperpendicu-70.Thedirectionofa0.045-Tmagneticfieldislartothelineofforce.Assumethatthe60.0ºabovethehorizontal.Awire,2.5-mconductortravelsataconstantvelocityoflong,moveshorizontallyat2.4m/s.1m/s.a.WhatistheverticalcomponentoftheWhentheconductorismovingperpen-magneticfield?diculartothelineofforceTheverticalcomponentofmagneticEind�BLvfieldis�(4.0T)(0.20m)(1m/s)Bsin60.0°�(0.045T)(sin60.0°)�0.8V�0.039Tb.WhatEMFisinducedinthewire?73.RefertoExampleProblem1andFigure25-24todeterminethefollowing.EMF�BLv�(0.039T)(2.5m)(2.4m/s)R�1.0�A�0.23Vv�3.6m/s71.DamsAgeneratoratadamcansupply375MW(375�106W)ofelectricalpower.EMFAssumethattheturbineandgeneratorareL�0.50m85percentefficient.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.FindtherateatwhichfallingwaterBoutofpagemustsupplyenergytotheturbine.AB�7.0�10�2TPouteff����100■ Figure25-24Pina.inducedvoltageintheconductor100Pin�Pout��ef�fEMFind�BLv�(7.0�10�2T)(0.50m)100�375MW����(3.6m/s)85�440MWinput�0.13Vb.Theenergyofthewatercomesfromab.current(I)changeinpotentialenergy,PE�mgh.EMFind0.13VWhatisthechangeinPEneededeachI������0.13AR1.0�second?c.directionoffluxrotationaroundthe440MW�440MJ/sconductor�4.4�108JeachsecondFluxrotatesclockwisearoundthec.Ifthewaterfalls22m,whatisthemassconductorwhenviewedfromabove.ofthewaterthatmustpassthroughthed.polarityofpointArelativetopointBturbineeachsecondtosupplythisPointAisnegativerelativetopointB.power?PE�mgh510SolutionsManualPhysics:PrinciplesandProblems
514Chapter25continued25.2ChangingMagneticFieldsInduceEMFVpIp�(120V)(30.0A)�3.6kWpage693VsIs�(1800V)(2.0A)�3.6kWLevel174.Theprimarycoilofatransformerhas76.LaptopComputersThepowersupplyina150turns.Itisconnectedtoa120-Vsource.laptopcomputerrequiresaneffectivevolt-Calculatethenumberofturnsontheageof9.0Vfroma120-Vline.secondarycoilneededtosupplythefollow-a.Iftheprimarycoilhas475turns,howingvoltages.manydoesthesecondarycoilhave?a.625VVNss�����VsNsVpNp�����VNppV(9.0V)(475)sNpN�����Vs�V120Vs625VpNs���V��Np���120�V�(150)p�36turns�781turns,whichroundsto780b.A125-mAcurrentisinthecomputer.Whatcurrentisintheprimarycircuit?b.35VVVpIp�VsIss35VNs���V��Np���120�V�(150)pVsIs(9.0V)(125mA)I�����p�V7200V�44turnspc.6.0V�9.4mAVs6.0VNs���V��Np���120�V�(150)Level2p77.HairDryersAhairdryermanufacturedfor�7.5turnsuseintheUnitedStatesuses10Aat120V.ItisusedwithatransformerinEngland,75.Astep-uptransformerhas80turnsonitswherethelinevoltageis240V.primarycoiland1200turnsonitssec-a.Whatshouldbetheratiooftheturnsofondarycoil.Theprimarycircuitissuppliedthetransformer?withanalternatingcurrentat120V.VNpp240V2.0a.Whatvoltageisbeingappliedacrossthe�����������VN120V1.0sssecondarycircuit?or2to1VNpp�����b.WhatcurrentwillthehairdryernowVNssdraw?VpNs(120V)(1200)VV������1.8kVpIp�VsIss�N80pVsIs(120V)(10A)b.ThecurrentinthesecondarycircuitisIp��V���240�V�5Ap2.0A.Whatcurrentisintheprimarycircuit?78.A150-WtransformerhasaninputvoltageVpIp�VsIsof9.0Vandanoutputcurrentof5.0A.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.VsIs(1.8�103V)(2.0A)a.Isthisastep-uporstep-downIp��V�����120Vtransformer?pPout�VsIs�3.0�101APout150W1Vc.WhatarethepowerinputandoutputofV������3.0�10s�I5.0Athetransformer?sstep-uptransformerPhysics:PrinciplesandProblemsSolutionsManual511
515Chapter25continuedb.WhatistheratioofVoutputtoVinput?V1A)pIp�(120V)(9.0�10P�VsIs�1.1�104WP150W1VVsIs�(3600V)(3.0A)�1.1�104WV������3.0�10s�I5.0As81.Withwhatspeedmusta0.20-m-longwireVoutput3.0�101V1.0�101��������cutacrossamagneticfieldforwhichBisV9.0V3.0input2.5TifitistohaveanEMFof10Vinducedor10to3init?EMF�BLv79.Scottconnectsatransformertoa24-VEMF10Vsourceandmeasures8.0Vatthesecondaryv������BL(2.5T)(0.20m)circuit.Iftheprimaryandsecondarycircuitswerereversed,whatwouldthenewoutput�20m/svoltagebe?82.Atwhatspeedmustawireconductor50-cmTheturnsratioisNVlongbemovedatrightanglestoamagneticss8.0V1.0�����������fieldofinduction0.20TtoinduceanEMFNV24V3.0ppof1.0Vinit?3.0Reversed,itwouldbe��.1.0EMF�BLvThus,thevoltagewouldnowbefoundbyEMF1.0VNVv������ssBL(0.20T)(0.5m)�����NVppN�1�101m/ssV��Vs��N�p�(3.0)(24V)�72Vp83.Ahouselightingcircuitisratedat120-Veffectivevoltage.WhatisthepeakvoltageMixedReviewthatcanbeexpectedinthiscircuit?pages693–694Veff�(0.707)VmaxLevel1Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.V80.Astep-uptransformer’sprimarycoilhasV�e�ff��120�V�170Vmax�0.7070.707500turns.Itssecondarycoilhas15,000turns.Theprimarycircuitisconnectedto84.ToasterAtoasterdraws2.5AofalternatinganACgeneratorhavinganEMFof120V.current.Whatisthepeakcurrentthrougha.CalculatetheEMFofthesecondarycircuit.thistoaster?VNppI�����eff�(0.707)ImaxVNssIeff2.5AVpNs(120V)(15,000)Imax��0.7�07���0.7073.5AV�����s�N500p85.Theinsulationofacapacitorwillbreakdown�3.6�103Viftheinstantaneousvoltageexceeds575V.b.FindthecurrentintheprimarycircuitifWhatisthelargesteffectivealternatingvolt-thecurrentinthesecondarycircuitis3.0A.agethatmaybeappliedtothecapacitor?VpIp�VsIsVmax575V������407Veff�VsIs(3600V)(3.0A)1A�2���2I������9.0�10p�V120Vp86.CircuitBreakerAmagneticcircuitbreakerc.Whatpowerisdrawnbytheprimarywillopenitscircuitiftheinstantaneouscircuit?Whatpowerissuppliedbythecurrentreaches21.25A.Whatisthelargestsecondarycircuit?effectivecurrentthecircuitwillcarry?512SolutionsManualPhysics:PrinciplesandProblems
516Chapter25continuedImax21.25ALevel2I������15.03Aeff��2��2�91.Awire,0.40-mlong,cutsperpendicularlyacrossamagneticfieldforwhichBis2.0T87.Theelectricityreceivedatanelectricalatavelocityof8.0m/s.substationhasapotentialdifferenceof240,000V.Whatshouldtheratioofthea.WhatEMFisinducedinthewire?turnsofthestep-downtransformerbetoEMF�BLvhaveanoutputof440V?�(2.0T)(0.40m)(8.0m/s)NsVs440V1�6.4V�����������NV240,000V545ppb.Ifthewireisinacircuitwitharesis-tanceof6.4W,whatisthesizeoftheprimary:secondary�545:1currentinthewire?88.Analternating-currentelectricgeneratorEMF�IRsuppliesa45-kWindustrialelectricheater.EMF6.4VI�������1.0AIfthesystemvoltageis660VR6.4�rms,whatisthepeakcurrentsupplied?92.Acoilofwire,whichhasatotallengthof45kWI���68A7.50m,ismovedperpendicularlytoEarth’srms�660Vmagneticfieldat5.50m/s.Whatisthesize68ATherefore,I�ofthecurrentinthewireifthetotalresis-peak�0.707�96Atanceofthewireis5.0�10�2m�?Assume89.Acertainstep-downtransformerhas100turnsEarth’smagneticfieldis5�10�5T.ontheprimarycoiland10turnsonthesec-EMF�BLvandV�IR,butEMF�V,ondarycoil.Ifa2.0-kWresistiveloadiscon-soIR�BLv,andnectedtothetransformer,whatistheeffectiveBLv(5.0�10�5T)(7.50m)(5.50m/s)primarycurrentthatflows?AssumethattheI��������R5.0�10�2m�secondaryvoltageis60.0Vpk.�4.1�10�2A�41mAVs,peak60.0VV������42.4Vs,eff��2��2�93.ThepeakvalueofthealternatingvoltageP2.0�103Wappliedtoa144-�resistoris1.00�102V.I������47As,eff�V42.4VWhatpowermusttheresistorbeabletos,effhandle?Ns10VIp,eff���N��Is,eff���10�0��47A��4.7AP�IVandV�IR,soI���therefore,pR90.Atransformerratedat100kVAhasanVV2(1.00�102V)2Pmax���R��V��R����144�efficiencyof98percent.a.Iftheconnectedloadconsumes98kW�69.4Wofpower,whatistheinputpowertotheTheaveragepowerisPmax/2sothetransformer?resistormustdissipate34.7W.Pout�98kW94.TelevisionTheCRTinatelevisionusesa98kW2kWPin��0.9�8�1.0�10step-uptransformertochange120Vto48,000V.Thesecondarysideofthetrans-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Whatisthemaximumprimarycurrentformerhas20,000turnsandanoutputofwiththetransformerconsumingits1.0mA.ratedreactivepower?AssumethatVa.HowmanyturnsdoestheprimarysideP�600V.have?100kVAI����200A600VPhysics:PrinciplesandProblemsSolutionsManual513
517Chapter25continuedVsNsPrimarycurrent:�����VNppPp757WI������6.05AN(20,000)(120V)p�Vp125VsVpN�����p�V48000Vs97.AnalyzeandConcludeAtransformerthat�50turnssupplieseighthomeshasanefficiencyof95percent.Alleighthomeshaveoperatingb.Whatistheinputcurrent?electricovensthateachdraw35AfromVpIp�VsIs240-Vlines.HowmuchpowerissuppliedVsIs(48,000V)(1.0�10�3A)totheovensintheeighthomes?HowIp��V�����120Vmuchpowerisdissipatedasheatintheptransformer?�0.40ASecondarypower:PThinkingCriticallys�(#ofhomes)VsIs�(8)(240V)(35A)�67kWpage69495.ApplyConceptsSupposethatan“anti-67kWissuppliedtotheovensintheLenz’slaw”existedthatmeantaforcewaseighthomes.exertedtoincreasethechangeinamagneticPrimarypower:field.Thus,whenmoreenergywasdemand-(100)P(100)(67W)P�s��ed,theforceneededtoturnthegeneratorp��e95�71kWwouldbereduced.WhatconservationlawThedifferencebetweenthesetwoisthewouldbeviolatedbythisnew“law”?Explain.powerdissipatedasheat,4kW.Itwouldviolatethelawofconversationofenergy.MoreenergywouldcomeoutWritinginPhysicsthanwentin.Ageneratorwouldcreatepage694energy,notjustchangeitfromoneform98.Commontools,suchasanelectricdrill,aretoanother.typicallyconstructedusingauniversalCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.motor.Usingyourlocallibrary,andother96.AnalyzeRealtransformersarenotsources,explainhowthistypeofmotor100percentefficient.WriteanexpressionformayoperateoneitherACorDCcurrent.transformerefficiencyinpercentusingpower.Astep-downtransformerthathasanAseriesDCMotorusesbothanarma-efficiencyof92.5percentisusedtoobtaintureandseriescoil.Whenoperated28.0Vfroma125-Vhouseholdvoltage.Theonalternatingcurrent,thepolarityoncurrentinthesecondarycircuitis25.0A.bothfieldschangessimultaneously.Whatisthecurrentintheprimarycircuit?Therefore,thepolarityofthemagneticfieldremainsunchanged,andhencetheEfficiencydirectionofrotationisconstant.Pse����100PpCumulativeReviewSecondarypower:page694P99.Lightisemittedbyadistantstaratas�VsIs�(28.0V)(25.0A)frequencyof4.56�1014Hz.Ifthestaris�7.00�102WmovingtowardEarthataspeedof2750Primarypower:km/s,whatfrequencylightwillbedetected2W)byobserversonEarth?(Chapter16)(100)P(100)(7.00�10P�s���p��e92.5�757Wf�v��obs�f�1c514SolutionsManualPhysics:PrinciplesandProblems
518Chapter25continuedBecausetheyaremovingtowardeachP�V2/Rother5.0WvV��PR���������(22�)��7.4Vfobs�f�1���2c14Hz)2.75�106m/s103.Determinethetotalresistanceofthree,�(4.56�10�1��3.00�108m/s�85-�resistorsconnectedinparalleland�4.60�104Hzthenseries-connectedtotwo85-�resistorsconnectedinparallel,asshownin100.AdistantgalaxyemitslightatafrequencyFigure25-25.(Chapter23)of7.29�1014Hz.ObserversonEarthreceivethelightatafrequencyof6.14�1014Hz.Howfastisthegalaxymov-�85�85�85�ing,andinwhatdirection?(Chapter16)ThegalaxyismovingawayfromEarth�becausetheobservedfrequencyislowerthantheemittedfrequency.To85�findthespeed:vfobs�f�1�c��85�■ Figure25-25Becausetheobservedlighthasalowerfrequency,thegalaxymustbe1111���������movingawayfromEarth.So,usetheR3inparallel85�85�85�negativeformoftheequationaboveR3inparallel�28.3�vfobs�f�1��c��111�������R85�85�f2inparallelobsv���1���fcR2inparallel�42.5�vfobsR�R�c��1��f�3inparallelR2inparallel�28.3�42.5�fv�c1�obs���f��71�6.14�1014Hz6m/s�(3.00�108m/s)�1���14Hz�104.Anelectronwithavelocityof2.1�107.29�10isatrightanglestoa0.81-Tmagneticfield.�4.73�107m/sWhatistheforceontheelectronproducedbythemagneticfield?Whatistheelec-101.Howmuchchargeisona22-�Fcapacitortron’sacceleration?Themassofanelec-with48Vappliedtoit?(Chapter21)tronis9.11�10�31kg.(Chapter24)qF�BqvC��V�(0.81T)(1.60�10�19C)(2.1�106m/s)q�CV�2.7�10�13N�(22�10�6F)(48V)F�maCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.1�10�3CF2.7�10�13Na�����m9.11�10�31kg102.Findthevoltageacrossa22-�,5.0-W�3.0�1017m/s2resistoroperatingathalfofitsrating.(Chapter22)Physics:PrinciplesandProblemsSolutionsManual515
519Chapter25continued3.Whatisthesecondarycurrentoftrans-ChallengeProblemformerT1?page68513V)Adistributiontransformer(TVs1���5��(3.0�101)hasitsprimarycoilconnectedtoa3.0-kVACsource.Thesecondarycoil�6.0�102Visconnectedtotheprimarycoilofasecondtrans-P210.3�103Wformer(T2)bycopperconductors.Finally,thesec-Is1���V��6.0�102V�17As1ondarycoiloftransformerT2connectstoaloadthatuses10.0kWofpower.TransformerT1hasa4.HowmuchcurrentistheACsourcesupply-turnratioof5:1,andT2hasaloadvoltageof120V.ingtoT1?Thetransformerefficienciesare100.0percentand1197.0percent,respectively.Ip1���5��Is1���5��(17A)�3.4A1.Calculatetheloadcurrent.PL10.0kWI��L��VL120V�83A2.HowmuchpowerisbeingdissipatedbytransformerT2?PL10.0kWP���2��0.9700.970�10.3kWP2ispowerinputtotransformerT2.Ofthe10.3kW,0.3kWisdissipatedbyT2;theother10.0kWisdissipatedintheload.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.516SolutionsManualPhysics:PrinciplesandProblems
520CHAPTER26ElectromagnetismPracticeProblems26.1InteractionsofElectricandMagneticFieldsandMatterpages697–704page700Assumethatallchargedparticlesmoveperpendiculartoauniformmagneticfield.1.Aprotonmovesataspeedof7.5�103m/sasitpassesthroughamagneticfieldof0.60T.Findtheradiusofthecircularpath.Notethatthechargecarriedbytheprotonisequaltothatoftheelectron,butispositive.mv2Bqv��rmvr���Bq(1.67�10�27kg)(7.5�103m/s)�����(0.60T)(1.60�10�19C)�1.3�10�4m2.Electronsmovethroughamagneticfieldof6.0�10�2Tbalancedbyanelectricfieldof3.0�103N/C.Whatisthespeedoftheelectrons?Bqv�EqE3.0�103N/Cv������B6.0�10�2T�5.0�104m/s3.Calculatetheradiusofthecircularpaththattheelectronsinproblem2followintheabsenceoftheelectricfield.mv2Bqv���rmvr���Bq(9.11�10�31kg)(5.0�104m/s)������4.7�10�6m(6.0�10�2T)(1.60�10�19C)4.Protonspassingwithoutdeflectionthroughamagneticfieldof0.60Tarebalancedbyanelectricfieldof4.5�103N/C.Whatisthespeedofthemovingprotons?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Bqv�EqE4.5�103N/Cv������B0.60T�7.5�103m/sPhysics:PrinciplesandProblemsSolutionsManual517
521Chapter26continuedpage7035.Abeamofsinglyionized(1�)oxygenatomsissentthroughamassspectrometer.ThevaluesareB�7.2�10�2T,q�1.60�10�19C,r�0.085m,andV�110V.Findthemassofanoxygenatom.B2r2q(7.2�10�2T)2(0.085m)2(1.60�10�19C)m����������2.7�10�26kg2V(2)(110V)6.Amassspectrometeranalyzesandgivesdataforabeamofdoublyionized(2�)argonatoms.Thevaluesareq�2(1.60�10�19C),B�5.0�10�2T,r�0.106m,andV�66.0V.Findthemassofanargonatom.B2r2q(5.0�10�2T)2(0.106m)2(2)(1.60�10�19C)m����������6.8�10�26kg2V(2)(66.0V)7.Astreamofsinglyionized(1�)lithiumatomsisnotdeflectedasitpassesthroughamagneticfieldof1.5�10�3Tthatisperpendiculartoanelectricfieldof6.0�102N/C.Whatisthespeedofthelithiumatomsastheypassthroughthetwofields?Bqv�EqE6.0�102N/Cv������B1.5�10�3T�4.0�105m/s8.InExampleProblem2,themassofaneonisotopeisdetermined.Anotherneonisotopeisfoundtohaveamassof22protonmasses.Howfarapartonthephotographicfilmwouldthesetwoisotopesland?Usethecharge-to-massratiotofindtheratiooftheradiiofthetwoisotopes.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.q2V����mB2r22Vm122r�B����q��m12Vm2222Thus,r�������and,����������Bqr2Vmm20�1�����20�20BqTheradiusoftheisotopewithamassof22protonmasses,then,ism22r��22�r20��m2022m�rp20���20mp22���r��202022�����(0.053m)20�0.056mThedifferenceintheradiiisr22�r20�0.056m�0.053m�0.003m�3mm518SolutionsManualPhysics:PrinciplesandProblems
522Chapter26continuedSectionReview26.1InteractionsofElectricandMagneticFieldsandMatterpages697–704page7049.Cathode-RayTubeDescribehowacathode-raytubeformsanelectronbeam.Electronsareemittedbythecathode,acceleratedbyapotentialdifference,andpassedthroughslitstoformabeam.10.MagneticFieldTheradiusofthecircularpathofanioninamassspectrometerisgivenbyr�(1/B)�2�Vm/q.Usethisequationtoexplainhowamassspectrometerisabletoseparateionsofdifferentmasses.Assumingalloftheionshavethesamecharge,theonlyvariablethatisnotconstantintheequationistheionmass,m.Asmincreases,theradiusoftheion’spathalsoincreases.Thisresultsinseparatepathsforeachuniquemass.11.MagneticFieldAmodernmassspectrometercananalyzemoleculeshavingmassesofhundredsofprotonmasses.Ifthesinglychargedionsofthesemole-culesareproducedusingthesameacceleratingvoltage,howwouldthemassspectrometer’smagneticfieldhavetobechangedfortheionstohitthefilm?Sincer�(1/B)�2�Vm�q,asmincreases,sotoomustB.Ifmisraisedbyafactorofabout10,Bwouldhavetoincreasebyafactorofabout3becausetokeeprconstant,Bmustincreaseas�m�.12.PathRadiusAprotonmovesataspeedof4.2�104m/sasitpassesthroughamagneticfieldof1.20T.Findtheradiusofthecircularpath.qv�����mBrvm(4.2�104m/s)(1.67�10�27kg)r���������3.7�10�4mqB(1.60�10�19C)(1.20T)13.MassAbeamofdoublyionized(2�)oxygenatomsisacceleratedbyapotentialdifferenceof232V.Theoxygenthenentersamagneticfieldof75mTandfollowsacurvedpathwitharadiusof8.3cm.Whatisthemassoftheoxygenatom?q2V����mB2r2qB2r2(2)(1.60�10�19C)(75�10�3T)2(8.3�10�2m)2m���������2V(2)(232V)�2.7�10�26kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual519
523Chapter26continued14.CriticalThinkingRegardlessoftheenergy20.Forlighttravelingthroughwater,theoftheelectronsusedtoproduceions,dielectricconstantis1.77.WhatistheJ.J.Thomsonnevercouldremovemorespeedoflighttravelingthroughwater?thanoneelectronfromahydrogenatom.c3.00�108m/sWhatcouldhehaveconcludedaboutthev������K��1.77�positivechargeofahydrogenatom?Itmustbeonlyasingleelementary�2.25�108m/scharge.21.Thespeedoflighttravelingthroughamaterialis2.43�108m/s.WhatisthePracticeProblemsdielectricconstantofthematerial?c26.2ElectricandMagneticv���K�FieldsinSpacec23.00�108m/s2pages705–713K���v�����2.43�1�08m/s��1.52page70615.Whatisthespeedinairofanelectromagneticwavehavingafrequencyof3.2�1019Hz?SectionReviewAllelectromagneticwavestravelthrough26.2ElectricandMagneticairoravacuumatc,3.00�108m/s.FieldsinSpacepages705–71316.Whatisthewavelengthofgreenlighthavingafrequencyof5.70�1014Hz?page71322.WavePropagationExplainhowelectro-c3.00�108m/s��������14Hz5.26�10�7mmagneticwavesareabletopropagatef5.70�10throughspace.17.AnelectromagneticwavehasafrequencyThechangingelectricfieldinducesaof8.2�1014Hz.Whatisthewavelengthchangingmagneticfield,andthechang-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofthewave?ingmagneticfieldinducesachangingc3.00�108m/selectricfield.Thewavespropagateas��������14Hz3.7�10�7mf8.2�10thesetwofieldsregenerateeachother.18.Whatisthefrequencyofanelectromagnetic23.ElectromagneticWavesWhataresomeofwavehavingawavelengthof2.2�10�2m?theprimarycharacteristicsofelectromagneticcwaves?Doelectromagneticwavesbehave����fdifferentlyfromthewaythatotherwaves,c3.00�108m/ssuchassoundwaves,behave?Explain.f��������2m1.4�1010Hz�2.2�10Electromagneticwavescanbedescribedbyfrequencyandwavelength.Theypage707behavesimilarlytootherwavesinthat19.Whatisthespeedofanelectromagnetictheyreflect,refract,diffract,interfere,andwavetravelingthroughtheair?UsecanbeDopplershifted.Thedifferencec�299,792,458m/sinyourcalculation.betweentheelectromagneticwavesandc299,792,458m/sotherwaves,suchassoundwaves,isv�������K��1.000�54�thatelectromagneticwavescantravelthroughavacuumandcanbepolarized.�2.99712�108m/s520SolutionsManualPhysics:PrinciplesandProblems
524Chapter26continued24.FrequencyAnelectromagneticwaveisscientistshavediscoveredthattheozonelayerfoundtohaveawavelengthof1.5�10�5m.overbothAntarcticaandtheArcticOceanisWhatisthefrequencyofthewave?thinning.Usewhatyouhavelearnedaboutcelectromagneticwavesandenergytoexplain����fwhysomescientistsareveryconcernedaboutthethinningozonelayer.c3.00�108m/s13Hzf�������2.0�10�1.5�10�5mIftheentireozonelayeristhinning,theamountofUVradiationfromtheSun25.TVSignalsTelevisionantennasnormallythatisblockedbytheozonelayerwillhavemetalrodelementsthatareorienteddecrease,allowingmoreUVraystohorizontally.Fromthisinformation,whatreachthesurfaceofEarth.Thewave-canyoudeduceaboutthedirectionsofthelengthsofUVwavesareshortenough,electricfieldsintelevisionsignals?andtheirenergiesarehighenough,toTheyalsomustbehorizontal.damageskinmolecules.Thus,theresultingincreaseinUVraystowhich26.ParabolicReceiversWhyisitimportanthumanswouldbeexposedcouldforaparabolicdish’sreceivingantennatoincreasetheprevalenceofskincancer.beproperlyalignedwiththetransmitter?ParabolicdishantennasareonlyabletoreceivesignalswithinaverynarrowChapterAssessmentrangeofangles.Itis,therefore,neces-ConceptMappingsarytocarefullyalignthedishreceiverpage718withthetransmittingantennastomaxi-30.Completethefollowingconceptmapmizethereceivedsignalstrength.usingthefollowingtermandsymbols:E,c,magneticfield.27.AntennaDesignTelevisionchannels2through6havefrequenciesjustbelowtheFMradioband,whilechannels7throughElectromagneticwaves13havemuchhigherfrequencies.Whichsignalswouldrequirealongerantenna:thoseofchannel7orthoseofchannel6?magnetictravelattheProvideareasonforyouranswer.electricfieldfieldspeedoflightThesignalsofchannel6wouldrequirealongerantenna.Lower-frequencywaveswouldhavelongerwavelengths.EBc28.DielectricConstantThespeedoflighttravelingthroughanunknownmaterialis1.98�108m/s.GiventhatthespeedoflightMasteringConceptsinavacuumis3.00�108m/s,whatisthepage718dielectricconstantoftheunknownmaterial?31.Whatarethemassandchargeofancelectron?(26.1)v���K�ThemassofanelectronisCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c23.00�108m/s29.11�10�31kg.K���v�����1.98�1�08m/s��2.30Itschargeis�1.60�10�19C.29.CriticalThinkingMostoftheUVradiation32.Whatareisotopes?(26.1)fromtheSunisblockedbytheozonelayerIsotopesareatomsofthesameelementinEarth’satmosphere.Inrecentyears,thathavedifferentmasses.Physics:PrinciplesandProblemsSolutionsManual521
525Chapter26continued33.ThedirectionofaninducedmagneticfieldApplyingConceptsisalwaysatwhatangletothechangingpage718electricfield?(26.2)38.TheelectronsinaThomsontubetravelfromAninducedmagneticfieldisalwaysatlefttoright,asshowninFigure26-14.rightanglestothechangingelectricfield.Whichdeflectionplateshouldbechargedpositivelytobendtheelectronbeamupward?34.WhymustanACgeneratorbeusedtopropagateelectromagneticwaves?IfaDCgeneratorwereused,whenwoulditcreateVUpperchargedelectromagneticwaves?(26.2)plateAnACgeneratorsuppliesthechangingelectricfield,whichinturngeneratesachangingmagneticfield.ADCgenera-Lowerchargedtorwouldonlygenerateachangingplateelectricfieldwhenturnedonoroff.35.Averticalantennawiretransmitsradio■Figure26-14waves.SketchtheantennaandtheelectricThetopplateshouldbechargedandmagneticfieldsthatitcreates.(26.2)positively.39.TheThomsontubeinquestion38usesamagneticfieldtodeflecttheelectronbeam.Whatwouldthedirectionofthemagneticfieldneedtobetobendthebeamdownward?Themagneticfieldwouldbedirected36.Whathappenstoaquartzcrystalwhenaintotheplaneofthepaper.voltageisappliedacrossit?(26.2)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.40.ShowthattheunitsofE/BarethesameasQuartzcrystalsbendordeformwhentheunitsforvelocity.voltageisplacedacrossthem.TheNquartzcrystalthenwillvibrateataset��Cfrequency.�E�����A��mBNC��A�m37.Howdoesanantenna’sreceivingcircuitBecause1Ais1C/s,thisbecomesselectelectromagneticradiowavesofacertainfrequencyandrejectallothers?(26.2)EC�mm��������Bs�CsByadjustingthecapacitanceoftheantennacircuit,theoscillationfrequency41.Thevacuumchamberofamassspectrome-ofthecircuitequalsthefrequencyoftheterisshowninFigure26-15.Ifasampleofdesiredradiowaves.Resonanceoccurs,ionizedneonisbeingtestedinthemasscausingtheelectronsinthecircuittospectrometer,inwhatdirectionmusttheoscillateatthatfrequency.magneticfieldbedirectedtobendtheionsintoaclockwisesemicircle?522SolutionsManualPhysics:PrinciplesandProblems
526Chapter26continuedChannel2waveshavealowerfrequencyandalongerwavelength,sochannel2requiresalongerantenna.ThelengthofVacuumchamberanantennaisdirectlyproportionaltoDeflectedwavelength.paths45.Supposetheeyesofanalienbeingaresensitivetomicrowaves.Wouldyouexpectsuchabeingtohavelargerorsmallereyesthanyours?Why?Theeyeswouldbemuchlarger,becausethewavelengthofmicrowaveradiationisFilmplatemuchlargerthanthatofvisiblelight.DualslitsMasteringProblemsIonbeam26.1InteractionsofElectricandMagneticFieldsandMatter■Figure26-15page719ThemagneticfieldisfoundbytheLevel1right-handruleandwouldbedirected46.Electronsmovingat3.6�104m/spassoutfromandperpendiculartotheplanethroughanelectricfieldwithanintensityofthepaper.of5.8�103N/C.Howlargeamagneticfield42.Ifthesignofthechargeontheparticlesinmusttheelectronsalsoexperiencefortheirquestion41ischangedfrompositivetopathtobeundeflected?negative,dothedirectionsofeitherorbothEv���ofthefieldshavetobechangedtokeeptheBparticlesundeflected?Explain.3E5.8�10N/CB�������0.16TYoucaneitherchangebothfieldsorv3.6�104m/sneitherfield,butyoucannotchange47.Aprotonmovesacrossa0.36-Tmagneticonlyonefield.field,asshowninFigure26-16.Iftheprotonmovesinacircularpathwitharadius43.Foreachofthefollowingproperties,of0.20m,whatisthespeedoftheproton?identifywhetherradiowaves,lightwaves,orXrayshavethelargestvalue.XBXXXXXa.wavelengthPathofchargedparticleRadiowaveshavethelongestXXXXXXwavelengths.b.frequencyXXXrXXXXrayshavethehighestfrequencies.c.velocityAlltravelatthesamevelocity,whichXXXXXXisthespeedoflight.■Figure26-16Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.44.TVWavesThefrequencyoftelevision�q���2v�mBrwavesbroadcastonchannel2isabout58MHz.Thewavesbroadcastonchannel7Brq(0.36T)(0.20m)(1.60�10�19C)v��������areabout180MHz.Whichchannelm1.67�10�27kgrequiresalongerantenna?�6.9�106m/sPhysics:PrinciplesandProblemsSolutionsManual523
527Chapter26continued48.Aprotonentersa6.0�10�2-Tmagneticfieldwithaspeedof5.4�104m/s.Whatistheradiusofthecircularpathitfollows?mv(1.67�10�27kg)(5.4�104m/s)r���������9.4�10�3mBq(6.0�10�2T)(1.60�10�19C)49.Anelectronisacceleratedbya4.5-kVpotentialdifference.Howstrongamagneticfieldmustbeexperiencedbytheelectronifitspathisacircleofradius5.0cm?12Vm1(2)(4.5�103V)(9.11�10�31kg)B������������r��q0.050m����1.60�10�19C�4.5�10�3T50.Amassspectrometeryieldsthefollowingdataforabeamofdoublyionized(2�)sodiumatoms:B�8.0�10�2T,q�2(1.60�10�19C),r�0.077m,andV�156V.Calculatethemassofasodiumatom.q2V����mB2r2qB2r2(2)(1.60�10�19C)(8.0�10�2T)2(0.077m)2m���������3.9�10�26kg2V(2)(156V)Level251.Analphaparticlehasamassofapproximately6.6�10�27kgandhasachargeof2�.Suchaparticleisobservedtomovethrougha2.0-Tmagneticfieldalongapathofradius0.15m.a.Whatspeeddoestheparticlehave?qv�����mBr�19C)(0.15m)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Bqr(2.0T)(2)(1.60�10v��������m6.6�10�27kg�1.5�107m/sb.Whatisitskineticenergy?11Bqr2q2B2r2(2)(1.60�10�19C)(2.0T)2(0.15m)2KE���mv2���m�������������22m2m(2)(6.6�10�27kg)�7.0�10�13Jc.Whatpotentialdifferencewouldberequiredtogiveitthiskineticenergy?KE�qVKE7.0�10�13J6VV���q���(2)(1.60�10�19C)�2.2�1052.Amassspectrometeranalyzescarbon-containingmoleculeswithamassof175�103protonmasses.Whatpercentdifferentiationisneededtoproduceasampleofmoleculesinwhichonlycarbonisotopesofmass12,andnoneofmass13,arepresent?524SolutionsManualPhysics:PrinciplesandProblems
528Chapter26continuedThedifferencebetweencarbon-1226.2ElectricandMagneticFieldsinSpaceandcarbon-13isoneprotonmass.page719Todistinguishbetweenthese,apercentLevel1differentiationofoneprotonmassout54.RadioWavesTheradiowavesreflectedbyaof175�103isneeded,orparabolicdishare2.0cmlong.Howlong11���100���percent.shouldtheantennabethatdetectsthewaves?175,0001750�Theantennais��,or1.0cmlong.53.SiliconIsotopesInamassspectrometer,2ionizedsiliconatomshavecurvatures,as55.TVAtelevisionsignalistransmittedonashowninFigure26-17.Ifthesmallercarrierfrequencyof66MHz.Ifthewiresonradiuscorrespondstoamassof28proton1areceivingantennaareplaced���apart,masses,whatisthemassoftheothersili-4conisotope?determinethephysicaldistancebetweenthereceivingantennawires.11c����������44fVacuumchamber83.00�10m/s���(4)(66�106Hz)r1�16.23cm�1.1mr2�17.97cm56.Bar-CodeScannerAbar-codescannerr2usesalaserlightsourcewithawavelengthr1ofabout650nm.Determinethefrequencyofthelaserlightsource.Filmplatec3.00�108m/s14Hzf�������4.6�10Dualslits�650�10�9mSiliconionbeam57.Whatistheoptimumlengthofareceivingantennathatistoreceivea101.3-MHzradiosignal?■Figure26-17Optimumantennalengthisq2V�����1����1��c�mB2r22�2�fsomisproportionaltor28m/s3.00�10mr2����(2)(101.3�106Hz)22�����mr211�1.48mr22m2�m1��r��1Level217.97cm258.AnEMwavewithafrequencyof100-MHz�(28mp)��16.23�cm��34mpistransmittedthroughacoaxialcablehav-m�27kg)ingadielectricconstantof2.30.Whatisthe2�34mp�(34)(1.67�10velocityofthewave’spropagation?�5.7�10�26kgc8m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.v�����3.00�10�1.98�108m/s�K��2.30�Physics:PrinciplesandProblemsSolutionsManual525
529Chapter26continued59.CellPhoneAcertaincellulartelephoneThefrequency,then,istransmitteroperatesonacarrierfrequencycf���of8.00�108Hz.Whatistheoptimallength(4)(0.083m)ofacellphoneantennadesignedtoreceive3.00�108m/s���thissignal?Notethatsingle-endedantennas,(4)(0.083m)suchasthoseusedbycellphones,generate�9.0�108HzpeakEMFwhentheirlengthisone-fourththewavelengthofthewave.63.AnunknownparticleisacceleratedbyaForasingle-endedantenna,optimumpotentialdifferenceof1.50�102V.Theantennalengthisparticlethenentersamagneticfieldof11c50.0mT,andfollowsacurvedpathwitha����������44fradiusof9.80cm.Whatistheratioofq/m?3.00�108m/sq���2V(4)(8.00�108Hz)�m���B2�r2�0.0938m(2)(1.50�102V)�����(50.0�10�3T)2(9.80�10�2m)2MixedReview�1.25�107C/kgpage720Level1ThinkingCritically60.Themassofadoublyionized(2�)oxygenatomisfoundtobe2.7�10�26kg.Ifthepage72064.ApplyConceptsManypolicedepartmentsmassofanatomicmassunit(amu)isequalto1.67�10�27kg,howmanyatomicmassuseradargunstocatchspeedingdrivers.Aradargunisadevicethatusesahigh-fre-unitsareintheoxygenatom?quencyelectromagneticsignaltomeasure(2.7�10�26kg)����1amu�16amuthespeedofamovingobject.Thefrequency1.67�10�27kgoftheradargun’stransmittedsignalis61.RadioAnFMradiostationbroadcastsknown.ThistransmittedsignalreflectsoffCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.onafrequencyof94.5MHz.Whatistheofthemovingobjectandreturnstotheantennalengththatwouldgivethebestreceiverontheradargun.Becausethereceptionforthisstation?objectismovingrelativetotheradargun,thefrequencyofthereturnedsignalisdif-Optimumantennalengthisferentfromthatoftheoriginallytransmit-11c�2�����2���f�tedsignal.ThisphenomenonisknownastheDopplershift.Whentheobjectismov-3.00�108m/s���6Hz)ingtowardtheradargun,thefrequencyof(2)(94.5�10thereturnedsignalisgreaterthanthefre-�1.59mquencyoftheoriginalsignal.IftheinitialtransmittedsignalhasafrequencyofLevel210.525GHzandthereturnedsignalshows62.AtwhatfrequencydoesacellphonewithaDopplershiftof1850Hz,whatisthean8.3-cm-longantennasendandreceivespeedofthemovingobject?Usethefollow-signals?Recallfromquestion59thatsingle-ingequation:endedantennas,suchasthoseusedbycellcfDopplerv��phones,generatepeakEMFwhentheirtarget�2ftransmittedlengthisone-fourththewavelengthoftheWhere,wavetheyarebroadcastingorreceiving.vtarget�velocityoftarget(m/s)Theantennalengthisc�speedoflight(m/s)11c0.083m�����������44f526SolutionsManualPhysics:PrinciplesandProblems
530Chapter26continuedfDoppler�Dopplershiftfrequency(Hz)ftransmitted�frequencyoftransmittedwave(Hz)cfDoppler(3.00�108m/s)(1850Hz)v�����target��2ftransmitted(2)(10.525�109Hz)�26.4m/s65.ApplyConceptsH.G.Wellswroteascience-fictionnovelcalledTheInvisibleMan,inwhichamandrinksapotionandbecomesinvisible,althoughheretainsallofhisotherfaculties.Explainwhyaninvisiblepersonwouldnotbeabletosee.Tosee,youmustdetectthelight,whichmeansthelightwillbeabsorbedorscattered.Essentially,aninvisiblepersonwouldbecompletelytransparentsolightwouldjustpassthroughtheeyewithouteverbeingabsorbedorscattered.66.DesignanExperimentYouaredesigningamassspectrometerusingtheprinciplesdiscussedinthischapter,butwithanelectronicdetectorreplacingthephotographicfilm.Youwanttodistinguishsinglyionized(1�)moleculesof175protonmassesfromthosewith176protonmasses,butthespacingbetweenadjacentcellsinyourdetectoris0.10mm.Themoleculesmusthavebeenaccel-eratedbyapotentialdifferenceofatleast500.0Vtobedetected.WhataresomeofthevaluesofV,B,andrthatyourapparatusshouldhave?Thecharge-to-massratioforisotopesinamassspectrometerisq2V12Vm����sotheradiusoftheisotope’spathisr�����.mB2r2B��qThedifferenceintheradiiforthetwoisotopesis0.10�10�3m�r176�r17512V��B����q����m176��m�175�12V��B����q���176�m�p��175�m�p�2Vm1p���������176���175��BqThemagneticfield,then,is��176���175��2VmpB���0.10�10�3m����q��176���175��(2)(500.0V)(1.67�10�27kg)���0.10�10�3m�������1.60�10�19C�1.2TTheradiusfortheisotopewithamassequalto176protonmasses2V(176m(2)(5.00V)(176)(1.67�10�27kg)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1p)1isr�����������76�B��q�1.2T����1.60�10�19C�3.6�10�2mWhendesigningthespectrometer,youcanchooseanyvalueofVandB,providedVisatleast500.0V.However,sinceq/misconstant,VwillbeproportionaltoB2r2.Physics:PrinciplesandProblemsSolutionsManual527
531Chapter26continuedWritinginPhysicsThespheressharechargesequallywhentheyaretouchedtogether,sotheypage720eachcarry–1qofcharge.Theforce67.Composea1–2pagereportinwhichyouvarieswiththeproductofthecharges,outlinetheoperationofatypicaltelevision,sothenewforceistotheoldforceasDVD,orVCRinfraredremote-controlunit.1q�1qisto4q�2q,or1:8.Therefore,Explainwhythesimultaneoususeofmulti-thenewforceisF/8.Thedirectionofthepleremote-controlunitstypicallydoesnotnewforcewillberepulsive,ratherthancausetheunitstointerferewitheachother.attractive.Yourreportshouldincludeblockdiagramsandsketches.70.WhatistheelectricfieldstrengthbetweenRemotecontrolsuseabroadrangeoftwoparallelplatesspaced1.2cmapartifaIRfrequenciesthatarepulse-codemod-potentialdifferenceof45Visappliedtoulated.Eachbuttonontheremotepro-them?(Chapter21)ducesauniquesequenceofshortand�V45V3V/morN/Clongpulses.BecauseofthewiderangeE�������3.8�10d0.012moffrequenciesusedbydifferentmanu-facturersandtheuniquepulsecodes71.Calculatethedailycostofoperatinganairused,itisveryunlikelythatdifferentcompressorthatrunsone-fourthofthetimeremotecontrolswillinterferewitheachanddraws12.0Afroma245-Vcircuitiftheother.costis$0.0950perkWh.(Chapter22)cost�(E)(rate)CumulativeReviewpage720�(IVt)(rate)68.AHe–Nelaser(��633nm)isusedtoillu-�(120A)(245V)(6h)minateaslitofunknownwidth,forminga$0.09501kWpatternonascreenthatislocated0.95m�������kWh1000Wbehindtheslit.Ifthefirstdarkbandis8.5mmfromthecenterofthecentralbright�$1.68Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.band,howwideistheslit?(Chapter19)72.A440-cmlengthofwirecarrying7.7Aisxw���1�atrightanglestoamagneticfield.TheforceLonthewireis0.55N.Whatisthestrength�Lofthefield?(Chapter24)w���x1F�BIL(633�10�9m)(0.95m)B��F�����8.5�10�3mIL0.55N�7.1�10�5m���(7.7A)(4.4m)�0.016T69.Theforcebetweentwoidenticalmetalsphereswiththechargesshownin73.Anorth-southwireismovedtowardtheFigure26-18isF.Ifthespheresareeastthroughamagneticfieldthatispoint-touchedtogetherandreturnedtotheiringdown,intoEarth.Whatisthedirectionoriginalpositions,whatisthenewforceoftheinducedcurrent?(Chapter25)betweenthem?(Chapter20)north�4q�2q■Figure26-18528SolutionsManualPhysics:PrinciplesandProblems
532Chapter26continued3.00�108m/s14Hzf����5.20�10ChallengeProblems5.77�10�7mpage709For��597nm,Visiblelightmakesuponlyaverysmallportionof3.00�108m/s14Hzf����5.03�10theentireelectromagneticspectrum.Thewavelengths5.97�10�7mforsomeofthecolorsofvisiblelightareshowninFor��622nm,Table26-1.3.00�108m/s14Hzf����4.82�106.22�10�7mTable26-1For��700nm,WavelengthsofVisibleLight3.00�108m/s14HzColorWavelength(nm)f����7m�4.29�107.00�10Violet–Indigo390to45514Hztoonesignificantdigit)(4�10Blue455to492Thus,therangesareGreen492to577Violet:6.59�1014Hzto7.69�1014HzYellow577to597Blue:6.10�1014Hzto6.59�1014HzOrange597to622Green:5.20�1014Hzto6.10�1014HzYellow:5.03�1014Hzto5.20�1014HzRed622to700Orange:4.82�1014Hzto5.03�1014HzRed:4.29�1014Hzto4.82�1014Hz1.Whichcoloroflighthasthelongestwave-length?red2.Whichcolortravelsthefastestinavacuum?Theyalltravelatthesamespeed,c.3.Waveswithlongerwavelengthsdiffractaroundobjectsintheirpathmorethanwaveswithshorterwavelengths.Whichcolorwilldiffractthemost?Theleast?Redlightwilldiffractthemost.Violetlightwilldiffracttheleast.4.CalculatethefrequencyrangeforeachcoloroflightgiveninTable26-1.cThefrequencyisf���.�For��390nm,3.00�108m/s14Hzf����7.69�103.90�10�7mFor��455nm,3.00�108m/s14HzCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.f����7m�6.59�104.55�10For��492nm,3.00�108m/s14Hzf����6.10�104.92�10�7mFor��577nm,Physics:PrinciplesandProblemsSolutionsManual529
533
534CHAPTER27QuantumTheoryKE��qVPracticeProblems0��(�1.60�10�19C)(3.2J/C)27.1AParticleModel�5.1�10�19JofWavespages723–734page732page7306.Thethresholdwavelengthofzincis310nm.1.Anelectronhasanenergyof2.3eV.WhatisFindthethresholdfrequency,inHz,andtheenergyoftheelectroninjoules?theworkfunction,ineV,ofzinc.1.60�10�19J�19J(2.3eV)��1e�V��3.7�10c3.00�108m/s14Hzf������9.7�100��310�10�9m02.WhatistheenergyineVofanelectronwithW�hf0avelocityof6.2�106m/s?�(6.63�10�34J/Hz)12KE��mv214Hz)1eV(9.7�10����1.60�10�19J����1(9.11�10�31kg)(6.2�106m/s)22�4.0eV�(1.75�10�17J)����1eV1.60�10�19J7.Theworkfunctionforcesiumis1.96eV.�1.1�102eVWhatisthekineticenergy,ineV,ofphoto-electronsejectedwhen425-nmvioletlight3.Whatisthevelocityoftheelectroninfallsonthecesium?problem1?1240eV�nmKE���hf�31kg,KE�1mv2max��0m�9.11�10�21240eV�nm����1.96eV2KE(2)(3.7�10�19J)425nmv��������m���9.11�10�31kg�0.960eV�9.0�105m/s8.Whenametalisilluminatedwith193-nm4.Thestoppingpotentialforaphotoelectricultravioletradiation,electronswithenergiescellis5.7V.Calculatethemaximumkineticof3.5eVareemitted.WhatistheworkenergyoftheemittedphotoelectronsineV.functionofthemetal?KE�hf�hfKE��qV00�19C)(5.7J/C)hc��(�1.60�10hf���KE0�hf�KE��1eV1240eV�nm����1.60�10�19J����KE��5.7eV1240eV�nmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.����3.5eV193nm5.Thestoppingpotentialrequiredtoprevent�2.9eVcurrentthroughaphotocellis3.2V.Calculatethemaximumkineticenergyinjoulesofthephotoelectronsastheyareemitted.Physics:PrinciplesandProblemsSolutionsManual531
535Chapter27continued9.Ametalhasaworkfunctionof4.50eV.13.PhotoelectricandComptonEffectsWhatisthelongest-wavelengthradiationDistinguishthephotoelectriceffectfromthatwillcauseittoemitphotoelectrons?theComptoneffect.hcTheComptoneffectisthescatteringofhf���4.50eV0�4.50eV,so�aphotonbymatter,resultinginapho-01240eV�nmtonoflowerenergyandmomentum.TheThus,���0��4.50eV276nmphotoelectriceffectistheemissionofelectronsfromametalsamplewhenradi-ationofsufficientenergyisincidentonit.SectionReview27.1AParticleModel14.PhotoelectricEffectGreenlight(��532nm)strikesanunknownmetal,ofWavescausingelectronstobeejected.Theejectedpages723–734electronscanbestoppedbyapotentialofpage7341.44V.Whatistheworkfunction,ineV,of10.PhotoelectricEffectWhyishigh-intensity,themetal?low-frequencylightunabletoejectelectronshc1240eV�nmE������2.33eVfromametal,whereaslow-intensity,high-greenlight��532nmfrequencylightcan?Explain.KEejectedelectron��qVLight,aformofelectromagneticradia-��(�1.60�10�19C)tion,isquantizedandmassless,yetitdoeshavekineticenergy.Eachincident(1.44J/C)photoninteractswithasingleelectron.If1eVtheincidentphotondoesnothavesuffi-����1.60�10�19Jcientenergy,itcannotejectanelectron.�1.44eVBecauseenergyisdirectlyrelatedtofre-quency,lowfrequencylightdoesnotW�Egreenlight�KEejectedelectronhavesufficientenergytoejectanelec-�2.33eV�1.44eVCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tron,whereashighfrequencylightdoes.�0.89eV11.FrequencyandEnergyofHot-Body15.EnergyofaPhotonWhatistheenergy,inRadiationAsthetemperatureofabodyiseV,ofthephotonsproducedbyalaserincreased,howdoesthefrequencyofpeakpointerhavinga650-nmwavelength?intensitychange?Howdoesthetotalamountofradiatedenergychange?hc1240eV�nmE�������1.9eV�650nmBothfrequencyofpeakintensityandtotalenergyradiatedincrease.Thepeak16.PhotoelectricEffectAnXrayisabsorbedinfrequencyincreasesasT,whereastheaboneandreleasesanelectron.IftheXraytotalenergyincreasesasT4.hasawavelengthofapproximately0.02nm,estimatetheenergy,ineV,oftheelectron.12.PhotoelectricandComptonEffectsAnexperimentersendsanXrayintoatarget.hc1240eV�nm4eVE�������6�10�0.02nmAnelectron,butnootherradiation,emergesfromthetarget.Explainwhether17.ComptonEffectAnXraystrikesabone,thiseventisaresultofthephotoelectriccollideswithanelectron,andisscattered.effectortheComptoneffect.HowdoesthewavelengthofthescatteredItisaresultofthephotoelectriceffect,XraycomparetothewavelengthofthewhichisthecaptureofaphotonbyanincomingXray?electroninmatterandthetransferofthephoton’senergytotheelectron.532SolutionsManualPhysics:PrinciplesandProblems
536Chapter27continuedThescatteredXrayhasalongerwave-21.WhatvoltageisneededtoaccelerateanlengththantheincomingXray.electronsoithasa0.125-nmwavelength?hh18.CriticalThinkingImaginethatthecolli-���p�,sop����sionoftwobilliardballsmodelstheinter-h2p2����actionofaphotonandanelectronduring12���KE���mv��theComptoneffect.Supposetheelectronis22m2mreplacedbyamuchmoremassiveproton.6.63�10�34J�sWouldthisprotongainasmuchenergy��0.125�1�0�9m����fromthecollisionastheelectrondoes?(2)(9.11�10�31kg)Wouldthephotonloseasmuchenergyasit�17J)1eVdoeswhenitcollideswiththeelectron?�(1.544�10����1.60�10�19JTheanswertobothquestionsisno.A�96.5eV,soitwouldhavetobetennisballcantransfermorekineticacceleratedthrough96.5V.energytoasoftballthanitcantoabowlingball.22.TheelectroninExampleProblem3hasadeBrogliewavelengthof0.14nm.Whatisthekineticenergy,ineV,ofaprotonPracticeProblems(m�1.67�10�27kg)withthesamewavelength?27.2MatterWaveshThedeBrogliewavelengthis����pages735–737mvhsothevelocityisv���page736m�19.A7.0-kgbowlingballrollswithavelocityThekineticenergy,then,isof8.5m/s.12�1h2h2KE��2�mv�2�m��m�����2m�2a.WhatisthedeBrogliewavelengthofthebowlingball?(6.63�10�34J�s)2������h6.63�10�34J�s(2)(1.67�10�27kg)(0.14�10�9m)2������mv(7.0kg)(8.5m/s)1eV��1.60���10�19J�1.1�10�35mb.Whydoesthebowlingballexhibitno�4.2�10�2eVobservablewavebehavior?Thewavelengthistoosmalltoshowobservableeffects.SectionReview27.2MatterWaves20.WhatisthedeBrogliewavelengthandpages735–737speedofanelectronacceleratedbyapoten-page737tialdifferenceof250V?23.WavelikePropertiesDescribetheexperi-�1�mv2�qV,somentthatconfirmedthatparticleshave2wavelikeproperties.2qV(2)(1.60�10�19C)(250J/C)v����m���������9.11�10�31kgWhenabeamofelectronswasaimedatacrystal,thecrystalactedlikeadiffractionCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�9.4�106m/sgrating,causingtheelectronstoformahdiffractionpattern.Thediffractionofthe����mvelectrons(particles)issimilartothedif-6.63�10�34J�sfractionoflight(waves)throughagrating.�����(9.11�10�31kg)(9.4�106m/s)�7.7�10�11mPhysics:PrinciplesandProblemsSolutionsManual533
537Chapter27continued24.WaveNatureExplainwhythewavenaturethebeampassedthrough,resultinginofmatterisnotobvious.thedistributionofphotonsoratomsThewavelengthsofmostobjectsareseenintheinterferencepattern.muchtoosmalltobedetected.28.CriticalThinkingPhysicistsrecentlymade25.DeBroglieWavelengthWhatistheadiffractiongratingofstandingwavesofdeBrogliewavelengthofanelectronlight.Atomspassingthroughthegratingacceleratedthroughapotentialdifferenceproduceaninterferencepattern.Ifthe1of125V?spacingoftheslitsinthegratingwere���2�2qV(about250nm),whatwastheapproximatev�����mdeBrogliewavelengthoftheatoms?�2(�1.60�10�19C)(125V)Fordiffractiongratings,��dsin�,��������9.11�10�31kgwheredisthespacingoftheslits,and�6.63�106m/s�istheangularseparationbetweenconsecutivepeaks.ThedeBrogliep�mv�(9.11�10�31kg)(6.63�106m/s)wavelength,then,is��(250nm)sin�.�6.04�10�24kg�m/sIfweassumesin�isaround0.1,thenh6.63�10�34J�sthedeBrogliewavelengthisafewtens�������p6.04�10�24kg�m/sofnanometers.�1.10�10�10m�0.110nmChapterAssessment26.WavelengthsofMatterandRadiationConceptMappingWhenanelectroncollideswithamassivepage742particle,theelectron’svelocityandwave-29.Completethefollowingconceptmapusinglengthdecrease.Howisitpossibletotheseterms:dualnature,mass,waveproper-increasethewavelengthofaphoton?ties,momentum,diffraction.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.IfthephotonundergoesComptonscat-teringwithafixedtarget,thewave-dualnaturelengthofthephotonwillincrease.Note,however,thatthephoton’sspeedisnotchanged.Thephotonstilltravelsatc.particlewavepropertiesproperties27.HeisenbergUncertaintyPrincipleWhenlightorabeamofatomspassesthroughadou-bleslit,aninterferencepatternforms.Bothinterferencediffractionmassmomentumresultsoccurevenwhenatomsorphotonspassthroughtheslitsoneatatime.HowdoestheMasteringConceptsHeisenberguncertaintyprincipleexplainthis?page742TheHeisenberguncertaintyprinciple30.IncandescentLightAnincandescentlight-statesthatyoucannotsimultaneouslybulbiscontrolledbyadimmer.Whathappensknowtheprecisepositionandmomen-tothecolorofthelightgivenoffbythebulbastumofaparticle.Thus,ifyouknowthethedimmercontrolisturneddown?(27.1)precisepositionofaphotonoranThelightbecomesredder.atomasitpassesthroughtheslit,youcannotknowitsprecisemomentum.Becauseoftheunknownmomentum,youcannotbesurewhichoftheslits534SolutionsManualPhysics:PrinciplesandProblems
538Chapter27continued31.Explaintheconceptofquantizedenergy.37.HowdoestheComptoneffectdemonstrate(27.1)thatphotonshavemomentumaswellasQuantizedenergymeansthatenergyenergy?(27.1)canexistonlyinmultiplesofsomemin-Elasticcollisionstransferbothmomen-imumvalue.tumandenergy.Onlyifphotonshavemomentumcantheequationsbe32.WhatisquantizedinMaxPlanck’sinterpre-satisfied.tationoftheradiationofincandescentbodies?(27.1)38.Themomentum,p,ofaparticleofmatterisThevibrationalenergyoftheincandes-givenbyp�mv.Canyoucalculatethecentatomsisquantized.momentumofaphotonusingthesameequation?Explain.(27.2)33.Whatisaquantumoflightcalled?(27.1)No,usingtheequationyieldsaphotonaphotonmomentumofzerobecausephotonsaremassless.Thisresultisincorrect34.Lightabovethethresholdfrequencyshinesbecausemasslessphotonshavenon-onthemetalcathodeinaphotocell.Howzeromomenta.doesEinstein’sphotoelectriceffecttheoryexplainthefactthatasthelightintensity39.Explainhoweachofthefollowingelectronincreases,thecurrentofphotoelectronspropertiescouldbemeasured.(27.2)increases?(27.1)a.chargeEachphotonejectsaphotoelectron.BalancetheforceofgravityagainstLightwithgreaterintensitycontainstheforceofanelectricfieldonthemorephotonspersecond;thus,itcharge.causestheejectionofmorephoto-b.masselectronspersecond.Balancetheforceofanelectricfieldagainstthatofamagneticfieldto35.ExplainhowEinstein’stheoryaccountsforfindm/q,thenusethemeasuredthefactthatlightbelowthethresholdfre-valueofq.quencyofametalproducesnophotoelec-trons,regardlessoftheintensityofthec.wavelengthlight.(27.1)ScatterelectronsoffacrystalandPhotonsbelowthethresholdfrequencymeasuretheanglesofdiffraction.donothavesufficientenergytoejectanelectron.Iftheintensityofthelight40.Explainhoweachofthefollowingphotonincreases,thenumberofphotonspropertiescouldbemeasured.(27.2)increasesbuttheirenergydoesnot;a.energythephotonsarestillunabletoejectanMeasuretheKEoftheelectronselectron.ejectedfromametalforatleasttwodifferentwavelengths,ormeasurethe36.PhotographicFilmBecausecertaintypesKEoftheelectronsejectedfromaofblack-and-whitefilmarenotsensitiveknownmetalatonlyonewavelength.toredlight,theycanbedevelopedinab.momentumdarkroomthatisilluminatedbyredlight.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ExplainthisonthebasisofthephotonMeasurethechangeinwavelengththeoryoflight.(27.1)ofXraysscatteredbymatter.Redphotonsdonothaveenoughenergyc.wavelengthtocausethechemicalreactionthatMeasuretheangleofdiffractionexposesfilm.whenlightpassesthroughtwoslitsPhysics:PrinciplesandProblemsSolutionsManual535
539Chapter27continuedoradiffractiongrating,measuretheofincidentphotonsorthebrightnessofwidthofasingle-slitdiffractionpat-thelight,notthefrequencyofthelight.tern,ormeasuretheanglethelightisbentwhenitpassesthroughaprism.44.Potassiumemitsphotoelectronswhenstruckbybluelight,whereastungstenemitsApplyingConceptsphotoelectronswhenstruckbyultravioletradiation.page74241.Usetheemissionspectrumofanincandes-a.Whichmetalhasahigherthresholdcentbodyatthreedifferenttemperaturesfrequency?showninFigure27-1onpage724toBluelighthasalowerfrequencyandanswerthefollowingquestions.energythanUVlight.Thus,tungstena.Atwhatfrequencydoesthepeakemis-hasthehigherthresholdfrequency.sionintensityoccurforeachofthethreeb.Whichmetalhasalargerworkfunction?temperatures?tungsten4000K:~2.5�1014Hz,5800K:~3.5�1014Hz,8000K:~4.6�1014Hz45.ComparethedeBrogliewavelengthoftheb.Whatcanyouconcludeabouttherela-baseballshowninFigure27-11withthetionshipbetweenthefrequencyofpeakdiameterofthebaseball.radiationemissionintensityandtem-peratureforanincandescentbody?Thefrequencyofthepeakintensityincreaseswithincreasing21m/s0.10mtemperature.c.Bywhatfactordoestheintensityoftheredlightgivenoffchangeasthebody’stemperatureincreasesfrom4000Kto8000K?■Figure27-11Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.TheintensityintheredportionofThediameterofthebaseballisaboutthespectrumincreasesfromapprox-0.10m,whereasthedeBrogliewave-lengthis10–34m;thebaseballisaboutimately0.5to9.2,anincreasebya1033timeslargerthanthewavelength.factorofslightlygreaterthan18.42.Twoironbarsareheldinafire.OneglowsMasteringProblemsdarkred,whiletheotherglowsbright27.1AParticleModelofWavesorange.page742–743a.Whichbarishotter?Level1therodglowingbrightorange46.AccordingtoPlanck’stheory,howdoestheb.Whichbarisradiatingmoreenergy?frequencyofvibrationofanatomchangeifitgivesoff5.44�10�19Jwhilechangingitstherodglowingbrightorangevalueofnby1?43.Willhigh-frequencylightejectagreaterE�nhf,sonumberofelectronsfromaphotosensitiveE5.44�10�19Jf�������surfacethanlow-frequencylight,assumingnh(1)(6.63�10�34J�s)thatbothfrequenciesareabovethethresh-�8.21�1014Hzoldfrequency?Notnecessarily;thenumberofejected47.Whatpotentialdifferenceisneededtostopelectronsisproportionaltothenumberelectronswithamaximumkineticenergyof4.8�10�19J?536SolutionsManualPhysics:PrinciplesandProblems
540Chapter27continuedKE��qV51.Thethresholdfrequencyofsodiumis0,so4.4�1014Hz.HowmuchworkmustbeKE4.8�10�19CV0����q������(�1.60�10�19C)3.0Vdonetofreeanelectronfromthesurfaceofsodium?48.WhatisthemomentumofaphotonofvioletWork�hf0lightthathasawavelengthof4.0�102nm?�(6.63�10�34J/Hz)(4.4�1014Hz)h6.63�10�34J�sp�������4.0�10�7m�2.9�10�19J�1.7�10�27kg�m/s15Hz52.Iflightwithafrequencyof1.00�10fallsonthesodiuminthepreviousprob-Level2lem,whatisthemaximumkineticenergyof49.Thestoppingpotentialofacertainmetalisthephotoelectrons?showninFigure27-12.Whatisthemaxi-KE�hf�hfmumkineticenergyofthephotoelectrons0inthefollowingunits?�h(f�f0)CathodeAnode�(6.63�10�34J/Hz)(1.00�1015Hz�4.4�1014Hz)�3.7�10�19JLevel353.LightMeterAphotographer’slightmeterusesaphotocelltomeasurethelightfallingonthesubjecttobephotographed.What�5.0V�shouldbetheworkfunctionofthecathodeifthephotocellistobesensitivetoredlight■Figure27-12(��680nm)aswellastotheothercolorsa.electronvoltsoflight?KE��qV01240eV�nm1240eV�nmW��������(�1elementarycharge)(5.0V)�680nm0�5.0eV�1.8eVb.joules5.0eV1.60�10�19J54.SolarEnergyAhomeusesabout4�1011J��������ofenergyeachyear.Inmanypartsofthe11eV�8.0�10�19JUnitedStates,thereareabout3000hofsunlighteachyear.50.Thethresholdfrequencyofacertainmetala.HowmuchenergyfromtheSunfallsonis3.00�1014Hz.Whatisthemaximumonesquaremetereachyear?kineticenergyofanejectedphotoelectronifEarthreceivesabout1000J/m2eachthemetalisilluminatedbylightwithasecond,sowavelengthof6.50�102nm?3600s3000hE�(1000J/m2�s)������KE�hf�hfhy0c�1�1010J/m2peryearCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�h����f0��b.Ifthissolarenergycanbeconverted�(6.63�10�34J�s)tousefulenergywithanefficiencyof3.00�108m/s14Hz20percent,howlargeanareaof���6.50�10�7m�3.00�10�converterswouldproducetheenergy�1.07�10�19Jneededbythehome?Physics:PrinciplesandProblemsSolutionsManual537
541Chapter27continued4�1011J6.63�10�34J/HzArea���������(0.2)(1�1010J/m2)(9.11�10�31kg)(4.2�107m/s)�2�102m2�1.7�10�11m�0.017nm58.Aneutronisheldinatrapwithakinetic27.2MatterWavesenergyofonly0.025eV.page743a.Whatisthevelocityoftheneutron?Level11.60�10�19J55.WhatisthedeBrogliewavelengthofanKE�(0.025eV)����eVelectronmovingat3.0�106m/s?�4.0�10�21Jh���mv12��mv26.63�10�34J�s�(9.11�����10�31kg)(3.0�106m/s)2KE(2)(4.0�10�21J)v��������m���1.67�10�27kg�2.4�10�10m�2.2�103m/s�0.24nmb.FindthedeBrogliewavelengthofthe56.Whatvelocitywouldanelectronneedtoneutron.haveadeBrogliewavelengthofh���3.0�10�10m?mvh6.63�10�34J�s�����(1.67�����10�27kg)(2.2�103m/s)mvh�1.8�10�10mv���m�6.63�10�34J/Hz59.Thekineticenergyofahydrogenatom’s�����(9.11�10�31kg)(3.0�10�10m)electronis13.65eV.�2.4�106m/sa.Findthevelocityoftheelectron.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12KE��mvLevel2257.Acathode-raytubeacceleratesanelectron2KEfromrestacrossapotentialdifferenceofv����m�3V.5.0�10(2)(13.65eV)(1.60�10�19J�eV)�����a.Whatisthevelocityoftheelectron?����9.11�10�31kg12�qV�2.19�106m/s��mv2b.Calculatetheelectron’sdeBroglieqVwavelength.v����1��mh2���mv(1.60�10�19C)(5.0�103V)v�����6.63�10�34kg�m/s�����1���31kg)�����(9.11�10�31kg)(2.19�106m/s)2(9.11�10�0.332nm�4.2�107m/sc.Giventhatahydrogenatom’sradiusisb.Whatisthewavelengthassociatedwith0.519nm,calculatethecircumferenceoftheelectron?ahydrogenatomandcompareitwithhthedeBrogliewavelengthfortheatom’s���mvelectron.C�2�r538SolutionsManualPhysics:PrinciplesandProblems
542Chapter27continued�(2�)(0.519nm)�3.26nmThecircumferenceisapproximatelyequaltotencompletewavelengths.Level360.AnelectronhasadeBrogliewavelengthof0.18nm.a.Howlargeapotentialdifferencediditexperienceifitstartedfromrest?hThedeBrogliewavelengthis���,mvhwhichgivesavelocityofv��.m�Thekineticenergy,then,is12KE��mv21h2��m����2m�h2��2m�2Intermsofvoltage,thekineticenergyisKE�qV.Combiningtheseandsolvingforvoltage,h2V��2mq�2(6.63�10�34J�s)2�������(2)(9.11�10�31kg)(1.60�10�19C)(0.18�10�9�47Vb.IfaprotonhasadeBrogliewavelengthof0.18nm,howlargeisthepotentialdifferencethatitexperiencedifitstartedfromrest?Usingthesamederivationasbefore,thevoltageish2V��2mq�2(6.63�10�34J�s)2�������(2)(1.67�10�27kg)(1.60�10�19C)(0.18�10�9m)2�0.025VMixedReviewpage743–744Level161.Whatisthemaximumkineticenergyofphotoelectronsejectedfromametalthathasastoppingpotentialof3.8V?KE��qV0��(�1elementarycharge)(3.8V)�3.8eV62.Thethresholdfrequencyofacertainmetalis8.0�1014Hz.WhatistheworkCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.functionofthemetal?W�hf0�(6.63�10�34J/Hz)(8.0�1014Hz)�5.3�10�19JPhysics:PrinciplesandProblemsSolutionsManual539
543Chapter27continued63.Iflightwithafrequencyof1.6�1015Hz�348m/s)(6.63�10J�s)(3.00�10fallsonthemetalinthepreviousproblem,����1.60�10�19Jwhatisthemaximumkineticenergyofthe(2.48eV)����1eVphotoelectrons?�5.01�10�7mKE�hf�hf0�501nm�(6.63�10�34J/Hz)(1.6�1015Hz)�5.3�10�19J67.AnelectronhasadeBrogliewavelengthof400.0nm,theshortestwavelengthofvisible�5.3�10�19Jlight.a.Findthevelocityoftheelectron.64.FindthedeBrogliewavelengthofadeuteron(nucleusof2Hisotope)ofmassh����3.3�10�27kgthatmoveswithaspeedofmv2.5�104m/s.hv���m�h���mv6.63�10�34J/Hz������34J�s(9.11�10�31kg)(400.0�10�9m)6.63�10�����(3.3�10�27kg)(2.5�104m/s)�1.82�103m/s�8.0�10�12mb.CalculatetheenergyoftheelectronineV.12Level2KE���mv265.Theworkfunctionofironis4.7eV.���1���31kg)(1.82�103m/s)2a.Whatisthethresholdwavelengthof2(9.11�10iron?eV����1.60�10�19Jhc1240eV�nmW���������6eV00�9.43�101240eV�nm1240eV�nm�0��W���4.7�eV68.ElectronMicroscopeAnelectronmicro-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.scopeisusefulbecausethedeBrogliewave-�2.6�102nmlengthsofelectronscanbemadesmallerthanb.Ironisexposedtoradiationofwave-thewavelengthofvisiblelight.Whatenergylength150nm.WhatisthemaximumineVhastobegiventoanelectronforittokineticenergyoftheejectedelectronshaveadeBrogliewavelengthof20.0nm?ineV?hThedeBrogliewavelengthis����,hchc1240eV�nmmvKE����������4.7eVh��0150nmwhichgivesavelocityofv���.m��3.6eVThekineticenergy,then,is1266.Bariumhasaworkfunctionof2.48eV.KE��2�mvWhatisthelongestwavelengthoflight21hthatwillcauseelectronstobeemitted���m����2m�frombarium?h2hc��2m�2Workfunction�2.48eV�hf��,so0��0(6.63�10�34J�s)2hc�0����������(2)(9.11�10�31kg)(20.0�10�9m)22.48eV1eV����1.60�10�19J�3.77�10�3eV540SolutionsManualPhysics:PrinciplesandProblems
544Chapter27continuedLevel3ThinkingCritically69.Incidentradiationfallsontin,asshowninpage744Figure27-13.Thethresholdfrequencyof70.ApplyConceptsAhelium-neonlaseremitstinis1.2�1015Hz.photonswithawavelengthof632.8nm.CathodeAnodea.Findtheenergy,injoules,ofeachphotonemittedbythelaser.EachphotonhasenergyhcE������167nm(6.63�10�34J�s)(3.00�108m/s)�����632.8�10�9m���3.14�10�19J■Figure27-13b.Atypicalsmalllaserhasapowerofa.Whatisthethresholdwavelengthoftin?0.5mW(equivalentto5�10�4J/s).Howmanyphotonsareemittedeachc��fsecondbythelaser?c3.00�108m/s�7m���f����1.2�1015Hz�2.5�10P5�10�4J/sn�������E3.14�10�19J/photonb.Whatistheworkfunctionoftin?�2�1015photons/sW�hf0�(6.63�10�34J/Hz)(1.2�1015Hz)71.ApplyConceptsJustbarelyvisiblelightwithanintensityof1.5�10�11W/m2�8.0�10�19Jentersaperson’seye,asshowninc.TheincidentelectromagneticradiationFigure27-14.hasawavelengthof167nm.WhatisthekineticenergyoftheejectedCorneaelectronsineV?KE�h�c�hf��550nmLensmax��0(6.63�10�34J/Hz)(3.00�108m/s)������167�10�9m8.0�10�19JPupil�3.9�10�19J(diameter�7.0mm)�19J)1eV■Figure27-14(3.9�10����1.60�10�19J�2.4eVa.Ifthislightshinesintotheperson’seyeandpassesthroughtheperson’spupil,whatisthepower,inwatts,thatenterstheperson’seye?Power�(intensity)(area)�(intensity)(�r2)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(1.5�10�11W/m2)(�(3.5�10�3m)2)�5.8�10�16WPhysics:PrinciplesandProblemsSolutionsManual541
545Chapter27continuedb.Usethegivenwavelengthoftheinci-Fromthegraph,thethresholdfrequencydentlightandinformationprovidedinisf14Hz,whichgivesa0�4.99�10cFigure27-14tocalculatethenumberofthresholdwavelengthof����0�fphotonspersecondenteringtheeye.8m/s03.00�10���601nmandawork4.99�1014HzEnergyperphotonfunctionofhcE���W�hf0(6.63�10�34J�s)(3.00�108m/s)�(6.63�10�34J/Hz)(4.99�1014Hz)�����550�10�9m�3.31�10�19J�3.62�10�19JWritinginPhysicsP5.8�10�16J/spage744n������E3.62�10�19J/photon73.Researchthemostmassiveparticleforwhichinterferenceeffectshavebeenseen.�1600photons/sDescribetheexperimentandhowtheinter-ferencewascreated.72.MakeandUseGraphsAstudentcompletedaphotoelectric-effectexperimentandrecordedAsof2003,thelargestisabuckyball,athestoppingpotentialasafunctionofwave-C60molecule.Nano-formedmetalliclength,asshowninTable27-1.Thephoto-gridswereusedasadiffractiongrating.cellhadasodiumcathode.Plotthedata(stoppingpotentialversusfrequency)anduseCumulativeReviewyourcalculatortodrawthebest-fitstraightpage744line(regressionline).Fromtheslopeand74.Thespringinapogostickiscompressedinterceptoftheline,findtheworkfunction,15cmwhenachildwhoweighs400.0Nthethresholdwavelength,andthevalueofstandsonit.Whatisthespringconstantofh/qfromthisexperiment.Comparethevaluethespring?(Chapter14)ofh/qtotheacceptedvalue.F�kxCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Table27-1F400Nk������x0.15mStoppingPotentialv.Wavelength�3�103N/m�(nm)V(eV)02004.2075.Amarchingbandsoundsflatasitplayson3002.06averycoldday.Why?(Chapter15)4001.05Answer:Thepitchofawindinstrumentdependsonthespeedofsoundinthe5000.41airwithinit.Thecoldertheair,thelower6000.03thespeedofsoundandtheflatterthepitchofthesoundproduced.Convertwavelengthtofrequencyandplot.Determinethebeststraightline76.Achargeof8.0�10�7Cexperiencesaforcethroughthedata.of9.0Nwhenplaced0.02mfromasecondSlope�4.18�10�15V/Hzcharge.Whatisthemagnitudeofthesec-�4.18�10�15J/Hz�Condcharge?(Chapter20)TheacceptedvalueisqAqBF�K�d2h(6.63�10�34J/Hz)�����e(1.60�10�19C)Fd2q��B�Kq�4.14�10�15J/Hz�CA542SolutionsManualPhysics:PrinciplesandProblems
546Chapter27continued(9.0N)(0.02m)21.Findthemaximumkineticenergyofthe�����(9.0�109N�m2�C2)(8.0�10�7C)vibratingobject.�5�10�7CKE��1mv2277.Ahomeownerbuysadozenidentical120-V����1(5.0�10�3kg)(1.0�10�2m/s)22lightsets.Eachlightsethas24bulbsconnect-edinseries,andtheresistanceofeachbulbis�2.5�10�7J6.0�.Calculatethetotalloadinamperesifthehomeowneroperatesallthesetsfroma2.Thevibratingobjectemitsenergyinsingleexterioroutlet.(Chapter23)theformoflightwithafrequencyof5.0�1014Hz.IftheenergyisemittedinItotal�12Isetasinglestep,findtheenergylostbytheVobject.�(12)���24RE�hf120V�(12)����(24)(6.0�)�(6.63�10�34J/Hz)(5.0�1014Hz)�1.0�101A�3.3�10�19J78.Theforceona1.2-mwireis1.1�10�3N.3.DeterminethenumberofequallysizedThewireisperpendiculartoEarth’smagneticenergy-stepreductionsthattheobjectfield.Howmuchcurrentisinthewire?wouldhavetomakeinordertoloseall(Chapter24)ofitsenergy.F�BIL2.5�10�7J11steps����7.6�103.3�10�19J/stepF1.1�103N1AI��������2�10BL(5�10�5T)(1.2m)ChallengeProblempage731Supposeanickelwithamassof5.0gvibratesupanddownwhileitisconnectedtoaspring.Themaximumvelocityofthenickelduringtheoscil-lationsis1.0cm/s.Assumethatthevibratingnickelmodelsthequantumvibrationsoftheelectronswithinanatom,wheretheenergyofthevibrationsisgivenbytheequationE�nhf.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Mass�5.0gMaximumvelocity�1.0cm/sPhysics:PrinciplesandProblemsSolutionsManual543
547
548CHAPTER28TheAtomr2(5.3�10�11m)PracticeProblems2�(2)�2.1�10�10mor0.21nm28.1TheBohrModelofr2(5.3�10�11m)theAtom3�(3)pages747–759�4.8�10�10mor0.48nmpage757r2(5.3�10�11m)4�(4)1.Calculatetheenergiesofthesecond,third,�8.5�10�10mor0.85nmandfourthenergylevelsinthehydrogenatom.5.Thediameterofthehydrogennucleusis�13.6eV2.5�10�15m,andthedistancebetweenE��n�n2thenucleusandthefirstelectronisabout�13.6eV5�10�11m.Ifyouuseaballwithadiame-E��2��(2)2�3.40eVterof7.5cmtorepresentthenucleus,how�13.6eVfarawaywilltheelectronbe?E��3��(3)2�1.51eV�11mx5�10������13.6eV0.075m2.5�10�15mE��4��(4)2�0.850eVx�2�103m�2km,about1mile!2.CalculatetheenergydifferencebetweenE3andE2inthehydrogenatom.page758�E�E�1�16.Findthewavelengthofthelightemittedin3�E2�(�13.6eV)�32�22�PracticeProblems2and3.Whichlinesin11Figure28-7correspondtoeachtransition?�(�13.6eV)��������1.89eV94hc���3to2��E3.CalculatetheenergydifferencebetweenE4andE(6.63�10�34J�s)(3.00�108m/s)2inthehydrogenatom.�����(1.89eV)(1.60�10�19J/eV)11�E�E4�E2�(�13.6eV)��42��22��6.58�10�7m�658nm11hc�(�13.6eV)��16���4���2.55eV�4to2����E(6.63�10�34J�s)(3.00�108m/s)4.Thetextshowsthesolutionoftheequation�����(2.55eV)(1.60�10�19J/eV)h2n2rn��4�2K�mq2forn�1,theinnermost�4.88�10�7m�488nmorbitalradiusofthehydrogenatom.Notethatwiththeexceptionofn2,allfactorsin7.Foraparticulartransition,theenergyofatheequationareconstants.Thevalueofmercuryatomdropsfrom8.82eVto6.67eV.r�11m,or0.053nm.Usethis1is5.3�10a.Whatistheenergyofthephotonemit-informationtocalculatetheradiioftheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.tedbythemercuryatom?second,third,andfourthallowableenergy�E�8.82eV�6.67eV�2.15eVlevelsinthehydrogenatom.r2k,wherek�5.3�10�11mn�n(Weareusingkforthecombinationofalltheconstantsintheequation.)Physics:PrinciplesandProblemsSolutionsManual545
549Chapter28continuedb.Whatisthewavelengthofthephoton11.BohrModelExplainhowenergyiscon-emittedbythemercuryatom?servedwhenanatomabsorbsaphotonofhclight.�����ETheinitialsumoftheenergyofthe(6.63�10�34J�s)(3.00�108m/s)electronintheatomplustheenergy�����(2.15eV)(1.60�10�19J/eV)oftheincidentphotonequalsthefinal�5.78�10�7m�578nmenergyoftheelectronintheatom.12.OrbitRadiusAheliumionbehaveslikea8.Thegroundstateofaheliumionishydrogenatom.Theradiusoftheion’slow-�54.4eV.Atransitiontothegroundstateestenergylevelis0.0265nm.Accordingtoemitsa304-nmphoton.WhatwastheBohr’smodel,whatistheradiusofthesec-energyoftheexcitedstate?ondenergylevel?hc�����E,soTheradiusdependsonn2,sothesecondlevelwouldhavearadiushc1240eV�nm�E�������4.08eVfourtimesthefirst,or0.106nm.�304nmThereforeEexcited�Eground��E13.AbsorptionSpectrumExplainhowthe��54.4eV�4.08eVabsorptionspectrumofagascanbedeter-��50.3eVmined.Describethereasonsforthespec-trum’sappearance.Toobtainanabsorptionspectrum,SectionReviewwhitelightispassedthroughasampleofgasandthenaspectroscope.28.1TheBohrModelofBecausethegasabsorbsspecificwave-theAtomlengths,thenormallycontinuousspec-pages747–759trumofwhitelightcontainsdarklines.page759Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.14.BohrModelHydrogenhasbeendetected9.Rutherford’sNuclearModelSummarizetransitioningfromthe101sttothe100ththestructureoftheatomaccordingtoenergylevels.Whatistheradiation’swave-Rutherford’snuclearmodel.length?Whereintheelectromagneticspec-InRutherford’snuclearmodel,allofantrumisthisemission?atom’spositivechargeandvirtuallyall�E�Eofitsmassareconcentratedinatiny,101�E100centrallylocatednucleusaroundwhich11�(�13.6eV)��2��2�negativelychargedelectronsorbit.101100�2.68�10�5eV,�10.SpectraHowdotheemissionspectraofhc1240eV�nmincandescentsolidsandatomicgasesdiffer?�������E2.68�10�5eVInwhatwaysaretheysimilar?�46.3�106nm�4.63cm,thewave-Incandescentsolidsproducespectralengthsindicatestheradiationisaconsistingofacontinuousbandofmicrowavecolors,whereasgasesproducespectramadeupofasetofdiscretelines.Allspectraarecreatedbyenergy-leveltransitionsinatoms.546SolutionsManualPhysics:PrinciplesandProblems
550Chapter28continued15.CriticalThinkingThenucleusoftheexplainwhythelawsofelectromagnet-hydrogenatomhasaradiusofaboutismdonotapplywithintheatom.1.5�10�15m.Ifyouweretobuildamodelofthehydrogenatomusingasoftball(r�19.QuantumModelExplainwhytheBohr5cm)torepresentthenucleus,wheremodeloftheatomconflictswiththewouldyoulocateanelectroninthen�1Heisenberguncertaintyprinciple,whereasBohrorbit?Woulditbeinyourclassroom?thequantummodeldoesnot.Thescaleis5cm�1.5�10�15m,orTheuncertaintyprincipledoesn’tallow1cm�3.0�10�16m.TheBohrradiusaparticletohaveapreciselyknownis5.3�10�11m.Inourmodelthiswouldposition,suchasaBohrorbit.Thebe(5.3�10�11/3.0�10�16)1cm�quantummodelpredictsonlytheproba-1.8�105cm,or1.8km.Thatwouldbebilitythattheradiusoftheelectronfarlargerthanmostschools.orbitwillhaveanygivenvalue.20.LasersExplainhowalasermakesuseofSectionReviewstimulatedemissiontoproducecoherentlight.28.2TheQuantumModelofWhenaphotonstrikesanatominthetheAtomexcitedstate,itstimulatestheexcitedpages760–765atomtoemitaphotonofthesameener-page765gyandinstepwiththeincidentphoton.16.LasersWhichofthelasersinTable28-1Theincidentphotonremainsunchangedemitsthereddestlight(visiblelightwiththeandthesetwophotonsinturnstrikelongestwavelength)?Whichofthelasersotherexcitedatoms,producingmoreemitbluelight?Whichofthelasersemitandmorein-step,coherentlight.beamsthatarenotvisibletothehumaneye?21.LaserLightWhatarethefourcharacteris-galliumaluminumarsenidelaserinred;ticsoflaserlightthatmakeituseful?argonionandindiumgalliumnitrideinblue.Krypton-fluorideexcimer,nitro-concentrated,highpower;directional;gen,galliumarsenide,neodymium,singlewavelength;coherentlightandcarbondioxidearenotvisibleto22.CriticalThinkingSupposethatanelec-thehumaneye.troncloudweretogetsosmallthatthe17.PumpingAtomsExplainwhethergreenatomwasalmostthesizeofthenucleus.lightcouldbeusedtopumparedlaser.UsetheHeisenberguncertaintyprincipletoWhycouldredlightnotbeusedtopumpexplainwhythiswouldtakeatremendousagreenlaser?amountofenergy.Yes.RedphotonshavelessenergythanThesmallertheelectroncloud,themoregreenones.Redphotonsdonothavepreciselyweknowthepositionoftheenoughenergytoputtheatomsinelectrons.Ifaparticle’spositioniswellenergylevelshighenoughtoenableknown,itsmomentummustbeuncer-themtoemitgreenphotons.tain.Theuncertaintyofthemomentumcanbelargeonlyifmomentumitselfis18.BohrModelLimitationsAlthoughitwaslarge.Therefore,thekineticenergyofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.abletoaccuratelypredictthebehavioroftheelectronalsomustbelarge,andithydrogen,inwhatwaysdidBohr’satomictakeslotsofenergytodothis.modelhaveseriousshortcomings?TheBohrmodelcouldnotpredictthebehaviorofanyotheratombesideshydrogen.ThemodelalsocouldnotPhysics:PrinciplesandProblemsSolutionsManual547
551Chapter28continuedAstheelectronsundergocentripetalChapterAssessmentacceleration,theywouldloseenergyConceptMappingandspiralintothenucleus.Inaddition,page770allatomsshouldradiateatallwave-23.Completethefollowingconceptmapusinglengths,notdiscretewavelengths.theseterms:energylevels,fixedelectronradii,27.AnalyzeandcritiquetheBohrmodeloftheBohrmodel,photonemissionandabsorption,atom.WhatthreeassumptionsdidBohrenergy-leveldifference.makeindevelopinghismodel?(28.1)stationarystates(quantizedenergyBohrmodellevels),atomemitsorabsorbsradiationhasonlywhenitchangesstates,angularmomentumisquantizedresults28.Gas-DischargeTubesExplainhowlinethatincludespectrafromgas-dischargetubesarepro-duced.(28.1)fixedelectronenergylevelphotonemissionradiiandabsorptionEnergyissuppliedtothegas,whichwithenergycausestheelectronstoexciteandmoveequaltotohigherenergylevels.Theelectronsenergy-leveldifferencethengiveoffthedifferenceinenergybetweenenergylevelsastheydropbackdowntoalessexcitedstate.TheMasteringConceptsenergydifferencesbetweenlevelscorre-page770spondstospectrallines.24.DescribehowRutherforddeterminedthatthepositivechargeinanatomisconcen-29.HowdoestheBohrmodelaccountforthetratedinatinyregion,ratherthanspreadspectraemittedbyatoms?(28.1)throughouttheatom.(28.1)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.PhotonwavelengthsaredeterminedbyHedirectedabeamofcharged�parti-thedifferenceinenergiesofallowedclesatathinmetalsheetandmeasuredlevelsaselectronsjumpinwardtothenumberofparticlesdeflectedatvar-stationarystates.iousangles.Thesmallbutsignificantnumberdepletedatwideanglesindi-30.Explainwhylinespectraproducedbycatesaconcentratednucleus.hydrogengas-dischargetubesaredifferentfromthoseproducedbyheliumgas-dis-25.HowdoestheBohrmodelexplainwhythechargetubes.(28.1)absorptionspectrumofhydrogencontainsEachelementhasadifferentconfigura-exactlythesamefrequenciesasitsemissiontionofelectronsandenergylevels.spectrum?(28.1)Bohrsaidtheenergyofanemitted31.LasersAlaboratorylaserhasapowerofphotonoranabsorbedphotonisequalonly0.8mW(8�10�4W).Whydoesittothechangeinenergyoftheatom,seemmorepowerfulthanthelightofawhichcanhaveonlyspecificvalues.100-Wlamp?(28.2)Lightisconcentratedintoanarrow26.Reviewtheplanetarymodeloftheatom.beam,ratherthanbeingspreadoveraWhataresomeoftheproblemswithawidearea.planetarymodeloftheatom?(28.1)548SolutionsManualPhysics:PrinciplesandProblems
552Chapter28continued32.AdevicesimilartoalaserthatemitsEnergyLevelDiagramforaMercuryAtommicrowaveradiationiscalledamaser.Whatwordslikelymakeupthisacronym?(28.2)Ionization(0.00)10.38E9(�1.56)8.82MicrowaveAmplificationbyStimulatedE8(�1.57)8.81EmissionofRadiationE7(�2.48)7.90E6(�2.68)7.7033.WhatpropertiesoflaserlightledtoitsuseE5(�3.71)6.67inlightshows?(28.2)E4(�4.95)5.43E3(�5.52)4.86Lasersaredirectionalandsingle,pureE2(�5.74)4.64colors.Energylevel(eV)ApplyingConceptsEnergyabovegroundstate(eV)page770E1(�10.38)0.0034.Asthecomplexityofenergylevelschanges■ Figure28-21fromatomtoatom,whatdoyouthinkhappenstothespectrathattheyproduce?No,ittakes5.43eVtoraisetheelectrontotheEGenerally,thespectrabecomemore4leveland6.67eVtoE5.Theatomcanabsorbonlyphotonsthatcomplex.haveexactlytherightenergy.35.NorthernLightsThenorthernlightsare39.Acertainatomhasfourenergylevels,withcausedbyhigh-energyparticlesfromtheESunstrikingatomshighinEarth’satmos-4beingthehighestandE1beingthelowest.Iftheatomcanmaketransitionsbetweenphere.Ifyoulookedattheselightsthroughanytwolevels,howmanyspectrallinescanaspectrometer,wouldyouseeacontinuoustheatomemit?Whichtransitionproducesorlinespectrum?Explain.thephotonwiththehighestenergy?Linespectrum;thelightcomesfromSixlinesarepossible.Egasmadeofspecificelements.4→E1hasthelargestphotonenergy.36.IfwhitelightwereemittedfromEarth’ssur-40.Aphotonisemittedwhenanelectroninanfaceandobservedbysomeoneinspace,excitedhydrogenatomdropsthroughener-woulditsspectrumappeartobecontinu-gylevels.Whatisthemaximumenergythatous?Explain.thephotoncanhave?IfthissameamountNo,aswhitelightpassedthroughofenergyweregiventotheatomintheEarth’satmosphere,certainenergiesgroundstate,whatwouldhappen?wouldbeabsorbedbythegasescom-Themaximumenergyis13.6eV.Thisposingtheatmosphere.Itsspectrum,isalsotheionizationenergyforhydro-therefore,wouldhaveblacklinesonit.gen.Theelectronwouldhaveenoughenergytoleavethenucleus.37.Ismoneyagoodexampleofquantization?Iswater?Explain.41.ComparethequantummechanicaltheoryYes.Moneycomesinonlycertaindis-oftheatomwiththeBohrmodel.cretevalues.No,waterseemstocomeTheBohrmodelhasfixedorbitalradii.inanypossiblequantity.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thepresentmodelgivesaprobabilityoffindinganelectronatalocation.The38.RefertoFigure28-21.Aphotonwithener-Bohrmodelallowsforcalculationofgyof6.2eVentersamercuryatomintheonlyhydrogenatoms.Thepresentgroundstate.Willitbeabsorbedbythemodelcanbeusedforallelements.atom?Explain.Physics:PrinciplesandProblemsSolutionsManual549
553Chapter28continued42.Givenared,green,andbluelaser,which45.Acalciumatomisinanexcitedstateattheproducesphotonswiththehighestenergy?E6energylevel.HowmuchenergyisBluelighthasahigherfrequencyandreleasedwhentheatomdropsdowntothetherefore,higherenergy.E2energylevel?RefertoFigure28-22.E6�E2�5.16eV�2.93eV�2.23eVMasteringProblems46.Aphotonoforangelightwithawavelength28.1TheBohrModeloftheAtomof6.00�102nmentersacalciumatominpage771theE6excitedstateandionizestheatom.Level1Whatkineticenergywilltheelectronhave43.Acalciumatomdropsfrom5.16eVaboveasitisejectedfromtheatom?thegroundstateto2.93eVabovethehcgroundstate.WhatisthewavelengthoftheE����photonemitted?(6.63�10�34J/Hz)(3.00�108m/s)�E�hf��h�c������7m6.00�10�1eV���hc��3.314J�3.314J����1.60�10�19J�E�2.07eV1240eV�nm����5.16eV�2.93eVEnergyneededtoionize6.08eV�556nmE6�5.16eV�0.92eV44.Acalciumatominanexcitedstate,E2,hasanenergylevel2.93eVabovethegroundPhotonenergy�ionizationenergy�state.Aphotonofenergy1.20eVstrikesthekineticenergycalciumatomandisabsorbedbyit.To2.07eV�0.92eV�1.15eVwhatenergylevelisthecalciumatomraised?RefertoFigure28-22.Level247.CalculatetheenergyassociatedwiththeE7Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.EnergyLevelDiagramforaCalciumAtomandtheE2energylevelsofthehydrogen6.08(Ionization)atom.6E9E105.58E7E85.325.49�15E6E7��13.6eV��n2E55.165.18E44.62E34.55��13.6eV���1��0.278eV44.137213E22.93E2��13.6eV���n212��13.6eV�����3.40eV221Energyabovegroundstate(eV)48.CalculatethedifferenceinenergylevelsinE1thepreviousproblem.01■ Figure28-22E�7��13.6eV��n22.93eV�1.20eV�4.13eV�E31��13.6eV���2��0.278eV7550SolutionsManualPhysics:PrinciplesandProblems
554Chapter28continued152.Usingthevaluescalculatedinproblem51,E�2��13.6eV��n2calculatethefollowingenergydifferences.1a.E��13.6eV���2��3.40eV6�E52(�0.378eV)�(�0.544eV)�0.166eVE7�E2��0.278eV�(�3.40eV)b.E6�E3�3.12eV(�0.378eV)�(�1.51eV)�1.13eVRefertoFigure28-21forProblems49and50.c.E4�E249.Amercuryatomisinanexcitedstateatthe(�0.850eV)�(�3.40eV)�2.55eVEd.E6energylevel.5�E2a.Howmuchenergywouldbeneededto(�0.544eV)�(�3.40eV)�2.86eVionizetheatom?e.E5�E3E6�7.70eV(�0.544eV)�(�1.51eV)�0.97eV10.38eV�7.70eV�2.68eV53.Usethevaluesfromproblem52todeter-b.Howmuchenergywouldbereleasedminethefrequenciesofthephotonsemit-iftheatomdroppeddowntothetedwhenanelectroninahydrogenatomE2energylevelinstead?makestheenergylevelchangeslisted.E2�4.64eVE7.70eV�4.64eV�3.06eVa.E�hf,sof��h�hf�E50.Amercuryatominanexcitedstatehasan6�E5�0.166eVenergyof�4.95eV.Itabsorbsaphoton(0.166eV)(1.60�10�19J/eV)f�����thatraisesittothenext-higherenergylevel.6.63�10�34J/HzWhatistheenergyandthefrequencyofthe13Hz�4.01�10photon?b.hf�EE6�E3�1.13eV5�E4��3.71eV�(�4.95eV)(1.13eV)(1.60�10�19J/eV)�1.24eVf�����6.63�10�34J/HzE�hf�2.73�1014HzEf���hc.hf�E4�E2�2.55eV1.60�10�19J1.24eV��eV��(2.55eV)(1.60�10�19J/eV)14Hzf���������6.63�10�34J�s2.99�106.63�10�34J/Hz�6.15�1014Hz51.Whatenergiesareassociatedwithahydro-d.hf�Egenatom’senergylevelsofE6�E3�2.86eV2,E3,E4,E5,andE6?(2.86eV)(1.60�10�19J/eV)f�����6.63�10�34J/Hz�13.6eV�13.6eVE2�����n2��(2)2�3.40eV�6.90�1014Hz�13.6eVe.hf�EE��6�E3�0.97eV3��(3)2�1.51eV(0.97eV)(1.60�10�19J/eV)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.E���13.6eVf�����6.63�10�34J/Hz4��(4)2�0.850eV�2.3�1014Hz�13.6eVE��5��(5)2�0.544eV54.DeterminethewavelengthsofthephotonsE���13.6eVhavingthefrequenciesthatyoucalculated6��(6)2�0.378eVinproblem53.Physics:PrinciplesandProblemsSolutionsManual551
555Chapter28continueda.c��fc3.00�108m/s�������f4.01�1013Hz�7.48�10�6m�7480nmc3.00�108m/sb.�������f2.73�1014Hz�1.10�10�6m�1.10�103nmc3.00�108m/sc.�������f6.15�1014Hz�4.88�10�7m�488nmc3.00�108m/sd.�������f6.90�1014Hz�4.35�10�6m�435nmc3.00�108m/se.�������f2.3�1014Hz�1.3�10�6m�1.3�103nmLevel355.Ahydrogenatomemitsaphotonwithawavelengthof94.3nmwhenitsfallstothegroundstate.Fromwhatenergyleveldidtheelectronfall?c��fc3.00�108m/s��������9.43�10�8m�3.18�1015HzE�34J/Hz)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.n�E1�(6.626�10(3.18�1015Hz)�2.11�10�18JE��2.11�10�18JEn�E1�E��2.17�10�18J�(�2.11�10�18J)��6�10�20J�2.17�10�18J�20J����6�10n2n2�36n�656.Forahydrogenatominthen�3Bohrorbital,findthefollowing.a.theradiusoftheorbitalh2n2r���4�2Kmq2(6.63�10�34J�s)2(3)2��������42(9.00�109N�m2/C2)(9.11�10�31kg)(1.60�10�19C)2�4.77�10�10m552SolutionsManualPhysics:PrinciplesandProblems
556Chapter28continuedb.theelectricforceactingbetweenthehc1240eV�nm�������protonandtheelectron�E2.90eV2�428nmKqF��r2b.Inwhatpartofthespectrumisthislight?(9.00�109N�m2/C2)(1.60�10�19C)2blue������(4.77�10�10m)2Level2�1.01�10�9N59.Acarbon-dioxidelaseremitsveryhigh-c.thecentripetalaccelerationofthepowerinfraredradiation.WhatistheenergyelectrondifferenceineVbetweenthetwolasingF�maenergylevels?ConsultTable28-1.F1.01�10�9Nc��fa������m9.11�10�31kgc3.00�108m/s�1.11�1021m/s2f�������10,600�10�9md.theorbitalspeedoftheelectron�2.83�1013Hz(ComparethisspeedwiththespeedE�hfoflight.)2(6.63�10�34J/Hz)(2.83�1013Hz)v�����a��r1.60�10�19J/eV�0.117eVv��ar���(1.11��10�21m/s�2)(4.�77�10��10m)�60.Thepowerinalaserbeamisequaltotheenergyofeachphotontimesthenumberof�7.28�105m/s,or0.24%ofcphotonspersecondthatareemitted.a.Ifyouwantalaserat840nmtohave28.2TheQuantumModeloftheAtomthesamepowerasoneat427nm,howpage771manytimesmorephotonspersecondLevel1areneeded?hc57.CDPlayersGalliumarsenidelasersareSinceE�hf���,theratioofenergy�commonlyusedinCDplayers.Ifsucha427ineachphotonis���0.508.840laseremitsat840nm,whatisthedifferenceTherefore,theratioofnumberofineVbetweenthetwolasingenergylevels?1photonspersecondis���1.97c��f0.508b.Findthenumberofphotonspersecondc3.00�108m/sf�������9ina5.0-mW840-nmlaser.�840�10m14HzP�(photons/s)(E/photon)�nEso�3.57�10n�P/E.E�hfCalculatetheenergyofthephoton(6.63�10�34J/Hz)(3.57�1014Hz)injoules.�����1.60�10�19J/eVhcE����1.5eV�(1240eV�nm)(1.60�10�19J/eV)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.58.AGaInNilaserlasesbetweenenergylevels�����840nmthatareseparatedby2.90eV.�19J;�2.4�10a.Whatwavelengthoflightdoesitemit?5.0�10�3J/shcSo,n����2.4�10�19J/photon�E�����2.1�1016photons/sPhysics:PrinciplesandProblemsSolutionsManual553
557Chapter28continuedLevel361.HeNeLasersTheHeNelasersusedinmanyclassroomscanbemadetolaseatthreewavelengths:632.8nm,543.4nm,and1152.3nm.a.Findthedifferenceinenergybetweenthetwostatesinvolvedinthegenera-tionofeachwavelength.hc1240eV�nm�E���,so�E���;��substitutingthethreevaluesof�gives1.96eV,2.28eV,and1.08eVb.Identifythecolorofeachwavelength.red,green,andinfrared,respectivelyMixedReviewpage772Level162.Aphotonwithanenergyof14.0eVentersahydrogenatominthegroundstateandionizesit.Withwhatkineticenergywilltheelectronbeejectedfromtheatom?Ittakes13.6eVtoionizetheatom,so14.0eV�13.6eV�0.4eVkineticenergy.63.CalculatetheradiusoftheorbitalassociatedwiththeenergylevelsE5andE6ofthehydrogenatom.h2n2(6.63�10�34J�s)2(5)2r���������5��4�2Kmq24�2(9.00�109N�m2/C2)(9.11�10�31kg)(1.60�10�19C)2�1.33�10�9m(6.63�10�34J�s)2(6)2r�������6�4�2(9.00�109N�m2/C2)(9.11�10�31kg)(1.60�10�19C)2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.91�10�9mLevel264.Ahydrogenatomisinthen�2level.a.Ifaphotonwithawavelengthof332nmstrikestheatom,showthattheatomwillbeionized.�13.6eV13.6eVE���2���n2(2)2�3.40eV,so3.40eVneededtoionizefromthislevel.hcE�hf����(6.63�10�34J/Hz)(3.00�108m/s)�����332�10�9m�5.99�10�19J�3.74eVYes,theatomisionized.554SolutionsManualPhysics:PrinciplesandProblems
558Chapter28continuedb.Whentheatomisionized,assumethatThinkingCriticallytheelectronreceivestheexcessenergypage772fromtheionization.Whatwillbethe67.ApplyConceptsTheresultofprojectingthekineticenergyoftheelectroninjoules?spectrumofahigh-pressuremercuryvapor3.74eV�3.40eV�0.340eVlampontoawallinadarkroomisshownin�5.4�10�20JFigure28-23.WhatarethedifferencesinenergylevelsforeachofthethreevisibleLevel3lines?65.Abeamofelectronsisdirectedontoasam-pleofatomichydrogengas.Whatminimumenergyoftheelectronsisneededforthehydrogenatomstoemittheredlightpro-ducedwhentheatomgoesfromthen�3tothen�2state?Theremustbeenoughenergytotransi-436nm546nm579nmtionastablehydrogenatomtothe■ Figure28-23n�3state.436nm(2.84eV)fromE6toE3since�E�E1240eV�nm3�E1���284eV;seeFig28-21to436nm�(�13.6eV)��1��1�findenergylevels.3212546nm(2.27eV)fromE6toE4�8�(�13.6eV)��9��579nm(2.14eV)fromE8toE5�12.1eV68.InterpretScientificIllustrationsAftertheemissionofthevisiblephotonsdescribedin66.Themostprecisespectroscopyexperimentsproblem67,themercuryatomcontinuestouse“two-photon”techniques.Twophotonsemitphotonsuntilitreachesthegroundwithidenticalwavelengthsaredirectedatstate.FromaninspectionofFigure28-21,thetargetatomsfromoppositedirections.determinewhetherornotanyofthesepho-Eachphotonhashalftheenergyneededtotonswouldbevisible.Explain.excitetheatomsfromthegroundstatetoNo.Thethreehighestenergylinesleavethedesiredenergylevel.Whatlaserwave-theatominstatesatleast4.64eVabovelengthwouldbeneededtomakeaprecisethegroundstate.Aphotonwiththisstudyoftheenergydifferencebetweenn�1energyhasawavelengthof267nminandn�2inhydrogen?theultraviolet.ThechangefromE4toE2�E�E2�E1involvesanenergychangeofonly0.79eV,resultinginlightwithawavelength11�(�13.6eV)��2��2�of1570nmintheinfrared.21�(�13.6eV)���3��69.AnaylzeandConcludeApositroniumatom4consistsofanelectronanditsantimatterrela-�10.2eVtive,thepositron,boundtogether.Althoughthelifetimeofthis“atom”isveryshort—ontheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Foreachlaser,averageitlivesone-seventhofamicrosecond—itsenergylevelscanbemeasured.TheBohrhc1240eV�nm������243nmmodelcanbeusedtocalculateenergieswith�E10.2eV��2����2��themassoftheelectronreplacedbyone-halfitsmass.Describehowtheradiioftheorbitsandtheenergyofeachlevelwouldbeaffected.Physics:PrinciplesandProblemsSolutionsManual555
559Chapter28continuedWhatwouldbethewavelengthoftheEatthepositionofthetestcharge?2toE1transition?(Chapter21)TheradiiwouldbetwiceaslargeF0.027N4N/CE�������9.0�10becausemappearsinthedenominatorq�3.00�10�7Coftheequation.Theenergieswouldbe73.Atechnicianneedsa4-�resistorbutonlyhashalfaslargebecausemappearsinthe1-�resistorsofthatvalue.Isthereawaytonumerator.Therefore,thewavelengthscombinewhatshehas?Explain.(Chapter23)wouldbetwiceaslarge.Thus,thelightemittedfromEYes.Putfour1�resistorsinseries.2toE1wouldbe(2)(121nm)�242nm.RT�R1�R2�R3�R4WritinginPhysics74.A1.0-m–longwireismovedatrightanglespage772toEarth’smagneticfieldwherethemagnetic70.Doresearchonthehistoryofmodelsoftheinductionis5.0�10�5Tataspeedofatom.Brieflydescribeeachmodelandiden-4.0m/s.WhatistheEMFinducedinthetifyitsstrengthsandweaknesses.wire?(Chapter25)Studentsshoulddescribethe“raisinEMF�BLvpudding”model,aclassicalplanetary�(5.0�10�5T)(1.0m)(4.0m/s)model,theBohrmodel,andthequantum�2.0�10�4V�0.20mVmodel.Thefirstexplainshowatomscanhaveelectronsandmass,butfailsto75.TheelectronsinabeammoveatdescribetheresultsofRutherford’s2.8�108m/sinanelectricfieldofexperiments.Theplanetaryexplains1.4�104N/C.WhatvaluemustthemagneticelectronsandRutherford’sresults,butisfieldhaveiftheelectronspassthroughtheunstableandwouldcollapseinabout1crossedfieldsundeflected?(Chapter26)ns.Bohr’sexplainsknownspectraandEfitsRutherford’snuclearmodel,buthasv���Bunexplainedassumptionsandfailsthe4Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.E1.4�10N/Cuncertaintyprinciple,aswellasbeingB������v2.8�108m/sunabletodescribeatomswithmore�5.0�10�5T�5.0�101�Tthanoneelectron.Thequantummodelcanexplainallknownfacts,butishard76.ConsiderthemodificationsthatJ.J.tovisualizeandrequirescomputerstoThomsonwouldneedtomaketohiscath-solvetheequations.ode-raytubesothatitcouldacceleratepro-tons(ratherthanelectrons),thenanswer71.Greenlaserpointersemitlightwithawave-thefollowingquestions.(Chapter26)lengthof532nm.Doresearchonthetypeoflaserusedinthistypeofpointeranda.Toselectparticlesofthesamevelocity,describeitsoperation.IndicatewhetherwouldtheratioE/Bhavetobechanged?thelaserispulsedorcontinuous.Explain.EItusesapulsedNdlaserat1064nm.No;V���,soratioissameforaBTheIRisputintoa“frequencydoubling”givenV.crystal.Lightwithhalfthatwavelength,b.Forthedeflectioncausedbythemag-or532nm,results.neticfieldalonetoremainthesame,wouldtheBfieldhavetobemadeCumulativeReviewsmallerorlarger?Explain.page7722mv72.Theforceonatestchargeof�3.00�10�7CFormagneticfieldonly,Bqv��ris0.027N.Whatistheelectricfieldstrength556SolutionsManualPhysics:PrinciplesandProblems
560Chapter28continuedmvandr���forabiggermass,BqBmustbebiggertokeepvconstant.77.Thestoppingpotentialneededtoreturnalltheelectronsejectedfromametalis7.3V.Whatisthemaximumkineticenergyoftheelectronsinjoules?(Chapter27)1.60�10�19JKE�(7.3eV)����1eV�1.2�10�18JChallengeProblempage759AlthoughtheBohratomicmodelaccuratelyexplainedthebehaviorofahydrogenatom,itwasunabletoexplainthebehaviorofanyotheratom.VerifythelimitationsoftheBohrmodelbyanalyzinganelectrontransitioninaneonatom.Unlikeahydrogenatom,aneonatomhastenelectrons.Oneoftheseelectronsmakesatransi-tionbetweenthen�5andthen�3energystates,emittingaphotonintheprocess.1.Assumingthattheneonatom’selectroncanbetreatedasanelectroninahydrogenatom,whatphotonenergydoestheBohrmodelpredict?11�E�E��i�Ef�(�13.6eV)�52�32��0.967eV2.Assumingthattheneonatom’selectroncanbetreatedasanelectroninahydrogenatom,whatphotonwavelengthdoestheBohrmodelpredict?hc1240eV�nm��������1280nm�E0.967eV3.Theactualwavelengthofthephotonemit-tedduringthetransitionis632.8nm.WhatisthepercenterroroftheBohrmodel’spre-dictionofphotonwavelength?Percenterror�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Acceptedvalue�Predictedvalue��������100Acceptedvalue632.8nm�1280nm�������100�103%6328nmThecalculatedwavelengthisroughlytwiceaslargeastheactualwavelength.Physics:PrinciplesandProblemsSolutionsManual557
561
562CHAPTER29Solid-StateElectronicsPracticeProblems29.1ConductioninSolidspages775–783page7781.Zinc,withadensityof7.13g/cm3andanatomicmassof65.37g/mol,hastwofreeelectronsperatom.Howmanyfreeelectronsarethereineachcubiccentimeterofzinc?�/cm3�2freee�6.02�1023atoms1mol7.13gfreee����atom����mol����65.37g��3�cm�1.31�1023freee�/cm32.Silverhas1freeelectronperatom.UseAppendixDanddeterminethenumberoffreeelectronsin1cm3ofsilver.�/cm3�1freee�6.02�1023atoms1mol10.49gfreee����atom����mol����107.87g���3cm�5.85�1022freee�/cm33.Goldhas1freeelectronperatom.UseAppendixDanddeterminethenumberoffreeelectronsin1cm3ofgold.�/cm3�1freee�6.02�1023atoms1mol19.32gfreee����atom����mol���196.97g����3cm�5.90�1022freee�/cm34.Aluminumhas3freeelectronsperatom.UseAppendixDanddeterminethenumberoffreeelectronsin1cm3ofaluminum.�/cm3�3e�6.02�1023atoms1mol2.70gfreee���atom����mol���26.982g����3cm�1.81�1023freee�/cm35.ThetipoftheWashingtonMonumentwasmadeof2835gofaluminumbecauseitwasarareandcostlymetalinthe1800s.Useproblem4anddeterminethenumberoffreeelectronsinthetipoftheWashingtonMonument.freee��(1.81�1023freee�/cm3)����2835g2.70g/cm3�1.90�1026freee�inthetipCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.page7806.Inpuregermanium,whichhasadensityof5.23g/cm3andanatomicmassof72.6g/mol,thereare2.25�1013freeelectrons/cm3atroomtemperature.Howmanyfreeelectronsarethereperatom?Physics:PrinciplesandProblemsSolutionsManual559
563Chapter29continued�/atom�1mol72.6gcm32.25�1013freee�freee�����6.02�1023atoms��1mol��5.23g�������cm3�5.19�10�10freee�/atom7.At200.0K,siliconhas1.89�105freeelectrons/cm3.Howmanyfreeelectronsarethereperatomatthistemperature?WhatdoesthistemperaturerepresentontheCelsiusscale?�/atom�1mol28.09gcm31.89�105freee�freee�����6.02�1023atoms��1mol��2.33g�������cm3�3.78�10�18freee�/atomTK�TC�273°TC�TK�273°�200.0°�273°��73°C8.At100.0K,siliconhas9.23�10�10freeelectrons/cm3.Howmanyfreeelectronsarethereperatomatthistemperature?WhatdoesthistemperaturerepresentontheCelsiusscale?�/atom�1mol28.09gcm39.23�10�10freee�freee�����6.02�1023atoms��1mol��2.33g�������cm3�1.85�10�32freee�/atomTK�TC�273°TC�TK�273°�100.0°�273°Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��173°C9.At200.0K,germaniumhas1.16�1010freeelectrons/cm3.Howmanyfreeelectronsarethereperatomatthistemperature?�/atom�1mol72.6gcm31.16�1010freee�freee�����6.02�1023atoms��1mol��5.23g�������cm3�2.67�10�13freee�/atom10.At100.0K,germaniumhas3.47freeelectrons/cm3.Howmanyfreeelectronsarethereperatomatthistemperature?�/atom�1mol72.6gcm33.47freee�freee�����6.02�1023atoms��1mol��5.23g�����cm3��8.00�10�23freee�/atompage78311.Ifyouwantedtohave1�104asmanyelectronsfromarsenicdopingasthermallyfreeelectronsinsiliconatroomtemperature,howmanyarsenicatomsshouldtherebepersiliconatom?FromExampleProblem3youknowthatthereare4.99�1022Siatoms/cm3,1.45�1010freee�/cm3inSi,and1freee�/Asatom.560SolutionsManualPhysics:PrinciplesandProblems
564Chapter29continuede�fromAs�(1�104)(freee�fromSi)However,theratioofatomsisneeded,notelectrons.e�fromAs(1�104)(freee�fromSi)Asatoms����freee�/atomAs���freee�/atomAsfreee�/cm3Sifreee�fromSi�(Siatoms)����Siatoms/cm3SubstitutingintotheexpressionforAsatomsyields4)(Siatoms)freee�/cm3Si(1�10���3�Siatoms/cmAsatoms�����/atomAsfreee4)freee�/cm3Si(1�10���3�AsatomsSiatoms/cm������/atomAsSiatomsfreee4)1.45�1010(1�10��4.99��1022�����1�2.91�10912.Ifyouwantedtohave5�103asmanyelectronsfromarsenicdopingasthermallyfreeelectronsinthegermaniumsemiconductordescribedinproblem6,howmanyarsenicatomsshouldtherebepergermaniumatom?Usingthesolutioninproblem11asagoby3)freee�/cm3Ge(5�10���3�AsatomsGeatoms/cm����freee��/atomAs�GeatomsFromproblem6,freee�/cm3Ge�2.25�103FromExampleProblem3,freee�/atomAs�13�6.02�1023atoms1mol5.23g22atoms/cm3Geatoms/cm����1mol����72.6g���3�4.34�10cm3)2.25�1013(5�10��Asatoms�4.34�1022�������Geatoms1�2.59�10�613.Germaniumat400.0K,has1.13�1015thermallyliberatedcarriers/cm3.Ifitisdopedwith1Asatomper1millionGeatoms,whatistheratioofdopedcarrierstothermalcarriers?Usethesolutiontoproblem12asastartingpoint.dopede�freee�/cm3Ge��Ge�e�����3�AsatomsGeatoms/cm�������Geatomsfreee/atomAsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.dopede�AsatomsGeatoms/cm3�/atomAs)��Gee������Geatoms���freee�/cm3Ge�(freee14.34�1022����1�106���1.13�1015�(1)�38.4Physics:PrinciplesandProblemsSolutionsManual561
565Chapter29continued14.Siliconat400.0K,has4.54�1012thermallyliberatedcarriers/cm3.Ifitisdopedwith1Asatomper1millionSi,whatistheratioofdopedcarrierstothermalcarriers?Usingthesolutionproblem13asagobydopede�AsatomsSiatoms/cm3�/atomAs)��Sie������Siatoms���freee�/cm3Si�(freee14.99�1022����1�106���4.54�1012�(1)�1.10�10415.Basedonproblem14,drawaconclusionaboutthebehaviorofgermaniumdevicesascomparedtosilicondevicesattemperaturesinexcessoftheboilingpointofwater.Germaniumdevicesdonotworkwellatsuchtemperaturesbecausetheratioofdopedcarrierstothermalcarriersissmallenoughthattemperaturehastoomuchinfluenceonconductivity.Siliconismuchbetter.SectionReview29.1ConductioninSolidspages775–783page78316.CarrierMobilityInwhichtypeofmaterial,aconductor,asemiconductor,oraninsulator,areelectronsmostlikelytoremainwiththesameatom?insulatorCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.17.SemiconductorsIfthetemperatureincreases,thenumberoffreeelectronsinanintrinsicsemiconductorincreases.Forexample,raisingthetemperatureby8°Cdoublesthenumberoffreeelectronsinsilicon.Isitmorelikelythatanintrinsicsemiconductororadopedsemiconductorwillhaveaconductivitythatdependsontemperature?Explain.Anintrinsiconebecauseallitsconductionisfromthermallyfreedelec-trons,whereasthedopedsemiconductordependsonthechargesfromthedopants,whichdependlittleontemperature.18.InsulatororConductor?Silicondioxideiswidelyusedinthemanufactureofsolid-statedevices.Itsenergy-banddiagramshowsagapof9eVbetweenthevalencebandandtheconductionband.Isitmoreusefulasaninsulatororaconductor?insulator19.ConductororInsulator?Magnesiumoxidehasaforbiddengapof8eV.Isthismaterialaconductor,aninsulator,orasemiconductor?insulator562SolutionsManualPhysics:PrinciplesandProblems
566Chapter29continued20.IntrinsicandExtrinsicSemiconductors24.DescribehowthediodesinthepreviousYouaredesigninganintegratedcircuitproblemshouldbeconnected.usingasinglecrystalofsilicon.YouwanttoTheanodeofoneconnectstothecath-havearegionwithrelativelygoodinsulat-odeoftheotherandthentheuncon-ingproperties.Shouldyoudopethisregionnectedanodemustbeconnectedtotheorleaveitasanintrinsicsemiconductor?positivesideofthecircuit.Leaveit.25.Describewhatwouldhappeninproblem21.CriticalThinkingSiliconproducesadou-23ifthediodeswereconnectedinseriesblingofthermallyliberatedcarriersforbutwithimproperpolarity.every8°Cincreaseintemperature,andger-Itwouldbeimpossibletoobtain2.5mAmaniumproducesadoublingofthermallyofcurrentwithanyreasonablepowerliberatedcarriersforevery13°Cincrease.Itsupplyvoltagebecauseoneofthewouldseemthatgermaniumwouldbediodeswouldbereverse-biased.superiorforhigh-temperatureapplications,buttheoppositeistrue.Explain.26.AgermaniumdiodehasavoltagedropofEventhoughrateofchangeforthermal0.40Vwhen12mApassesthroughit.Ifacarrierproductionisgreaterforsilicon,470-�resistorisusedinseries,whatbatteryatanygiventemperaturesiliconshowsvoltageisneeded?farfewerthermallyliberatedcarriers.6.0VVb�IR�VdPracticeProblems�(0.012A)(470�)�0.40V�6.0V29.2ElectronicDevicespages784–789page786SectionReview22.Whatbatteryvoltagewouldbeneededtoproduceacurrentof2.5mAinthediodein29.2ElectronicDevicesExampleProblem4?pages784–7891.7Vpage78927.TransistorCircuitTheemittercurrentinaUsingFig.29-10,thediodehastransistorcircuitisalwaysequaltothesumVd�0.50Vat2.5mAofthebasecurrentandthecollectorcur-Vb�IR�Vdrent:IE�IB�IC.Ifthecurrentgainfromthebasetothecollectoris95,whatisthe�(0.0025A)(470�)�0.50Vratioofemittercurrenttobasecurrent?�1.7VIGain���C95IB23.Whatbatteryvoltagewouldbeneededtoproduceacurrentof2.5mAifanotherIE�IB�ICidenticaldiodewereaddedinserieswithDividebothsidesbyIthediodeinExampleProblem4?B.IIV�E�1���C1�95�96b�IR�Vd�VdCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.IIBB�(0.0025A)(470�)�0.50V�0.50V96to1�2.2VPhysics:PrinciplesandProblemsSolutionsManual563
567Chapter29continued28.DiodeVoltageDropIfthediodecharac-ChapterAssessmentterizedinFigure29-10isforward-biasedbyabatteryandaseriesresistorsothatthereisConceptMappingmorethan10mAofcurrent,thevoltagepage794dropisalwaysabout0.70V.Assumethat33.Completetheconceptmapusingthefol-thebatteryvoltageisincreasedby1V.lowingterms:transistor,silicondiode,emitsa.Byhowmuchdoesthevoltageacrosslight,conductsbothways.thediodeorthevoltageacrosstheresis-torincrease?CircuitComponentsBecausethevoltageacrossthediodeisalways0.70V,thevoltageacrosstheresistorincreasesby1V.coppersiliconLEDtransistorb.Byhowmuchdoesthecurrentthroughwirediodetheresistorincrease?1VThecurrentincreasesbyI��.conductsconductsemitsRamplifiesbothwaysonewaylight29.DiodeResistanceComparetheresistanceofapn-junctiondiodewhenitisforward-MasteringConceptsbiasedandwhenitisreverse-biased.page794Itconductsmuchbetterwhenforward-34.Howdotheenergylevelsinacrystalofanbiased,soitsresistanceismuchsmall-elementdifferfromtheenergylevelsinaerwhenforward-biasedthanwhensingleatomofthatelement?(29.1)reverse-biased.Theenergylevelsofasingleatomhavediscreteanduniquevalues.Theenergy30.DiodePolarityInalight-emittingdiode,levelsinacrystalhaveasmallrangewhichterminalshouldbeconnectedtothearoundthevaluesfoundinasinglep-endtomakethediodelight?atom.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.TheLEDmustbeforward-biased,sothepositiveterminalmustbeconnectedto35.Whydoesheatingasemiconductorincreasethep-end.itsconductivity?(29.1)Ahighertemperaturegiveselectrons31.CurrentGainThebasecurrentinatransis-additionalenergy,permittingmoreelec-torcircuitmeasures55�Aandthecollectortronstoreachtheconductiveband.currentmeasures6.6mA.Whatisthecur-rentgainfrombasetocollector?36.Whatisthemaincurrentcarrierinap-typeIC6.6mAsemiconductor?(29.1)Gain������120I0.055mABpositively-chargedholes32.CriticalThinkingCouldyoureplacean37.Anohmmeterisaninstrumentthatplacesanpn-transistorwithtwoseparatediodescon-potentialdifferenceacrossadevicetobenectedbytheirp-terminals?Explain.tested,measuresthecurrent,anddisplaysNo,thep-regionofannpn-transistortheresistanceofthedevice.Ifyouconnectmustbethinenoughtoallowelectronsanohmmeteracrossadiode,willthecur-topassthroughthebasetothecollector.rentyoumeasuredependonwhichendofthediodewasconnectedtothepositiveter-minaloftheohmmeter?Explain.(29.2)Yes,onewayyouforward-biasthediode;theotherwayyoureverse-biasit.564SolutionsManualPhysics:PrinciplesandProblems
568Chapter29continued38.Whatisthesignificanceofthearrowheadat43.Theresistanceofgraphitedecreasesastem-theemitterinatransistorcircuitsymbol?peraturerises.Doesgraphiteconductelec-(29.2)tricitymorelikecopperormorelikesiliconThearrowheadshowsthedirectionofdoes?theconventionalcurrent.morelikeSi39.Describethestructureofaforward-biased44.Whichofthefollowingmaterialswoulddiode,andexplainhowitworks.(29.2)makeabetterinsulator:onewithaforbiddenAforward-biaseddiodehasap-typegap8-eVwide,onewithaforbiddengapandann-typesemiconductorlayer,3-eVwide,oronewithnoforbiddengap?connectedtowiresoneitherendonewithan8-eVgapthroughmetalcaps.Thep-typelayerisconnectedtothepositiveterminalof45.Consideratomsofthethreematerialsinthebattery.Newholesarecreatedintheproblem44.Fromwhichmaterialwoulditp-typelayerandthoseholesmovebemostdifficulttoremoveanelectron?towardtheboundarybetweenthetwoonewithan8-eVgapsemiconductors.Newelectronsareaddedtothen-typelayer,andthose46.StatewhetherthebulbineachofthecircuitselectronsmovetowardtheboundaryofFigure29-17(a,b,andc)islighted.betweenthetwosemiconductors.Astheholesandelectronscombine,thecircuitiscompletedandthereiscur-rent.Thecurrentdirectionisfromthep-typesemiconductortothen-type.ApplyingConceptsabcpages794–795■Figure29-1740.Fortheenergy-banddiagramsshownincircuita:no,circuitb:no,circuitc:yesFigure29-16,whichonerepresentsamate-rialwithanextremelyhighresistance?47.InthecircuitshowninFigure29-18,statewhetherlampL1,lampL2,both,orneitherislighted.L1L2abc■Figure29-16■Figure29-1841.Fortheenergy-banddiagramsshowninFigure29-16,whichhavehalf-fullconduc-L1ison,L2isoff.tionbands?48.Usetheperiodictabletodeterminewhichaofthefollowingelementscouldbeaddedtogermaniumtomakeap-typesemicon-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.42.Fortheenergy-banddiagramsshownductor:B,C,N,P,Si,Al,Ge,Ga,As,In,Sn,inFigure29-16,whichonesrepresentorSb.semiconductors?B,Al,Ga,InbPhysics:PrinciplesandProblemsSolutionsManual565
569Chapter29continued49.DoesanohmmetershowahigherresistanceMasteringProblemswhenapn-junctiondiodeisforward-biased29.1ConductioninSolidsorreverse-biased?page795ThediodewillhavealowerresistanceLevel1whenitisforward-biased.53.Howmanyfreeelectronsexistinacubiccen-timeterofsodium?Itsdensityis0.971g/cm3,50.Iftheohmmeterinproblem49showstheitsatomicmassis22.99g/mol,andthereislowerresistance,istheohmmeterleadon1freeelectronperatom.thearrowsideofthediodeatahigheror�lowerpotentialthantheleadconnectedtofreee�/cm3����1etheotherside?atomhigherpotential,morepositive6.02�1023atoms0.971gmol�����mol��3���22.99g�cm51.Ifyoudopepuregermaniumwithgallium�2.54�1022freee�/cm3alone,doyouproducearesistor,adiode,oratransistor?Level2Youmakearesistorbecausethereisno54.Atatemperatureof0°C,thermalenergyjunction.frees1.55�109e�/cm3inpuresilicon.Thedensityofsiliconis2.33g/cm3,andthe52.Drawthetime-versus-amplitudewaveformatomicmassofsiliconis28.09g/mol.WhatforpointAinFigure29-19aassumingisthefractionofatomsthathavefreeaninputACwaveformasshowninelectrons?Figure29-19b.6.02�1023atoms2.33gmol�����mol��3���28.09g�cm1.55�109e�/cm3aA�3.22�1013atom/e�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.29.2ElectronicDevicespage795Level1bTime55.LEDThepotentialdropacrossaglowingLEDisabout1.2V.InFigure29-20,theACvoltagepotentialdropacrosstheresistoristhedif-■Figure29-19ferencebetweenthebatteryvoltageandtheLED’spotentialdrop.Whatisthecurrentthrougheachofthefollowing?TimeVoltageR�240�OutputVoltageBattery1.2VV�6.0VLEDPointAisnegativewithrespecttogroundandthegraphshowsthatthealternatingpolarityoftheinputwaveform■Figure29-20hasbeenrectifiedtoanegativepolarity.a.theLEDVb�IR�Vd566SolutionsManualPhysics:PrinciplesandProblems
570Chapter29continuedVb.Determinethecollectorcurrent.I���b�VdRbydefinition:whenthebasecurrent6.0V�1.2Viszero,soisthecollectorcurrent���240�c.Determinethevoltmeterreading.�2.0�101mA15Vb.theresistorWithnocurrentflow,thedrop2.0�101mAacrossthecollectorresistoriszeroandthereisa15-Vdropacrossthe56.Jonwantstoraisethecurrentthroughthetransistor.LEDinproblem55upto3.0�101mAsothatitglowsbrighter.Assumethatthe59.AssumethattheswitchshowninFigure29-potentialdropacrosstheLEDisstill1.2V.21ison,andthatthereisa0.70-VdropWhatresistorshouldbeused?acrossthebase-emitterjunctionandacur-Vb�Vd6.0V�1.2Vrentgainfrombasetocollectorof220.R�������160�I3.0�101mAa.Determinethebasecurrent.VI��Level2R57.DiodeAsilicondiodewithI/Vcharacteris-3.5V�0.70Vtics,asshowninFigure29-10,isconnected���120,000�toabatterythrougha270-�resistor.The�2.3�10�5Abatteryforward-biasesthediode,andthediodecurrentis15mA.Whatisthebatteryb.Determinethecollectorcurrent.voltage?I�C�220IVb�IR�VdBIVC�220IBd�0.70V(fromfigure)V�(220)(2.3�10�5A)b�(15mA)(270�)�0.70V�5.1�10�3A�4.8Vc.Determinethevoltmeterreading.Level3Findthedropacrossthe1500�58.Assumethattheswitchshowninresistor:Figure29-21isoff.Vresistor�IRA�(5.1�10�3A)(1500�)�7.7V1500�15VThemeterisconnectedacrossthetransistor,120,000�Vbattery�Vresistor�VtransistorAVVmeter�Vtransistor3.5V�Vbattery�Vresistor■Figure29-21Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�15V�7.7Va.Determinethebasecurrent.�7.3Vbyinspection,thebasecircuitisoff,soitiszeroPhysics:PrinciplesandProblemsSolutionsManual567
571Chapter29continuedMixedReviewbandtothevalenceband.FindthewidthoftheforbiddengapineVinthisdiode.pages795–7961240eV�nmLevel1E����2.25eV550nm60.Theforbiddengapinsiliconis1.1eV.Electromagneticwavesstrikingthesilicon64.RefertoFigure29-22.causeelectronstomovefromthevalencebandtotheconductionband.Whatisthelongestwavelengthofradiationthatcould220�exciteanelectroninthisway?RecallthatE�1240eV�nm/�.Alldiodesaresilicon.1240eV�nmV����1.1eV10.0V�1100nminthenearinfraredA1A2Level261.SiDiodeAparticularsilicondiodeat0°C■Figure29-22showsacurrentof1.0nAwhenitisreverse-a.Determinethevoltmeterreading.biased.Whatcurrentcanbeexpectedifthe0.70Vtemperatureincreasesto104°C?Assumebyinspectionandtheapproximationthatthereverse-biasvoltageremainscon-thatasilicondiodewilldrop0.70Vstant.(Thethermalcarrierproductionofsil-whenitisforwardbiasedicondoublesforevery8°Cincreaseinb.DeterminethereadingofAtemperature.)1.104°C0ANumberof8°Cincreases��8°Cbyinspection;0.70Visnotenough�13toturnontwodiodesinseries.Thecurrentwilldouble13timesc.DeterminethereadingofA2.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Currentat104°C�(1nA)(213)�8.2�AI���V��10.0V�0.70V�42mAR220�62.GeDiodeAparticulargermaniumdiodeatThinkingCritically0°Cshowsacurrentof1.5�Awhenitispage796reverse-biased.Whatcurrentcanbeexpected65.ApplyConceptsAcertainmotor,inifthetemperatureincreasesto104°C?Figure29-23,runsinonedirectionwithaAssumethatthereverse-biasingvoltagegivenpolarityappliedandreversesdirectionremainsconstant.(Thethermalcharge-withtheoppositepolarity.carrierproductionofgermaniumdoublesforevery13°Cincreaseintemperature.)�M�M104°CNumberof13°Cincreases���813°C��abThecurrentwilldouble8times.��Currentat104°C�(1.5�A)(28)�380�AcLevel3M63.LEDAlight-emittingdiode(LED)producesgreenlightwithawavelengthof550nm��whenanelectronmovesfromtheconduction■Figure29-23568SolutionsManualPhysics:PrinciplesandProblems
572Chapter29continueda.Whichcircuit(a,b,orc)willallowthe9.0V�2.5VR��motortoruninonlyonedirection?2�0.040A�160�a67.ApplyConceptsSupposethatthetwob.WhichcircuitwillcauseafusetoblowLEDsinproblem66arenowconnectediniftheincorrectpolarityisapplied?series.Ifthesamebatteryistobeusedandbacurrentof0.035Aisdesired,whatresistorc.Whichcircuitproducesthecorrectdirec-shouldbeused?tionofrotationregardlessoftheVR����b�(VD1�VD2)appliedpolarity?Ic9.0V�(1.75V�2.5V)�����140�d.Discusstheadvantagesanddisadvan-0.035Atagesofallthreecircuits.WritinginPhysicsThecircuitatahastheadvantageofsimplicity.Ithasthedisadvantageofpage796dropping0.70V,whichcanbe68.ResearchthePauliexclusionprincipleandimportantinlow-voltagecircuits.thelifeofWolfgangPauli.HighlighthisThecircuitatbhastheadvantageofoutstandingcontributionstoscience.notwasting0.70V.Ithasthedisad-Describetheapplicationoftheexclusionvantageofhavingtoreplacefuses.principletothebandtheoryofconduction,Thecircuitatchastheadvantageofespeciallyinsemiconductors.alwaysworking,regardlessofpolari-Studentanswerswillvary.Studentsty.Ithasthedisadvantageofwast-coulddiscusshiscontributionstoing1.4V.quantummechanics,thePaulimatrices,hissuggestionofaneutral,massless66.ApplyConceptsTheI/Vcharacteristicsofparticleinbetadecay(theneutrino),twoLEDsthatglowwithdifferentcolorsareandhisproofofthespin-statisticsshowninFigure29-24.Eachistobecon-theorem.nectedthrougharesistortoa9.0-Vbattery.Ifeachistoberunatacurrentof0.040A,69.Writeaone-pagepaperdiscussingtheFermiwhatresistorsshouldbechosenforeach?energylevelasitappliestoenergy-banddiagramsforsemiconductors.IncludeatLEDCurrentv.Voltageleastonedrawing.Studentanswerswillvary,butshouldindicatethattheFermienergyisthe0.04energyofthehighestoccupiedstateatabsolutezero.Itapplieswhenthereare0.02manyelectronsinasystem,andthus,Current(A)theelectronsareforcedintohigherenergylevelsduetothePauliexclusion00.5121.52.5principle.Voltage(V)■Figure29-24Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Vb�IR�VDVR���b�VDI9.0V�1.75VR��1�0.040A�180�Physics:PrinciplesandProblemsSolutionsManual569
573Chapter29continuedCumulativeReviewpage79670.Analphaparticle,adoublyionized(2�)heliumatom,hasamassof6.7�10�27kgandisacceleratedbyavoltageof1.0kV.Ifauniformmagneticfieldof6.5�10�2Tismaintainedonthealphaparticle,whatwillbetheparticle’sradiusofcurvature?(Chapter26)12Vmr�����Bq1(2)(1.0�103V)(6.7�10�27kg)���(6.5�10�2T)��������(2)(1.60�10�19C)�0.010m71.Whatisthepotentialdifferenceneededtostopphotoelectronsthathaveamaximumkineticenergyof8.0�10�19J?(Chapter27)KE�8.0�10�19J����1eV1.60�10�19J�5.0eV,so5.0V72.CalculatetheradiusoftheorbitalassociatedwiththeenergylevelE4ofthehydrogenatom.(Chapter28)h2n2r���4�2Kmq2(6.627�10�34J�s)2(4)2��������4�2(8.99�109N�m2/C2)(9.11�10�31kg)(1.60�10�19C)2�8.49�10�10m�0.849nmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ChallengeProblempage786ApproximationsoftenareusedindiodeDiodeCurrentv.Voltagecircuitsbecausedioderesistanceisnotcon-stant.Fordiodecircuits,thefirstapproxima-14.0tionignorestheforwardvoltagedropacross12.0thediode.Thesecondapproximationtakesintoaccountatypicalvalueforthediodevolt-10.0agedrop.Athirdapproximationusesaddi-tionalinformationaboutthediode,oftenin8.0theformofagraph,asshownintheillustra-Graphicsolutiontiontotheright.Thecurveisthecharacteristic6.0Current(mA)current-volatagecurveforthediode.The4.0straightlineshowscurrent-voltageconditionsforallpossiblediodevoltagedropsfora180-2.0�resistor,a1.8-Vbattery,andadiode,fromazerodiodevoltagedropand10.0mAatone0.00.20.61.01.41.8end,toa1.8-Vdrop,0.0mAattheotherend.Voltage(V)UsethediodecircuitinExampleProblem4withVb�1.8V,butwithR�180�:570SolutionsManualPhysics:PrinciplesandProblems
574Chapter29continued1.Determinethediodecurrentusingthefirstapproximation.V1.8V1mAI�����1.0�10R180�2.Determinethediodecurrentusingthesec-ondapproximationandassuminga0.70-Vdiodedrop.V1.8V�0.70VI������6.1mAR180�3.Determinethediodecurrentusingthethirdapproximationbyusingtheaccompanyingdiodegraph.Thestraightlinerepresentsallthepos-sibleconditionsfora180-�resistoranda1.8-Vbattery(fromadiodevolt-agedropof0.0Vat10.0mAononeendtoa1.8-Vdropat0.0mAontheotherend).ThesolutionistheintersectionofbothlinesandoccursatI�6.3mA.4.Estimatetheerrorforallthreeapproxima-tions,ignoringthebatteryandresistor.Discusstheimpactofgreaterbatteryvolt-agesontheerrors.Forthefirstapproximation,theerroris(10.0mA�6.1mA)/6.1mA,or64percent(whentheactualdiodedropis0.70V).Thiserrordecreasesforgreaterbatteryvoltages.Forthesecondapproximation,theerrorsourceisanydeviationfrom0.70Vastheactualdiodedrop.Itcannotbeexactlydetermined,butit’smuchlessthan64percent.Thiserroralsodecreaseswithhigherbatteryvoltages.Forthethirdapproximation,theerrorisduetograph-icresolutionandisnotaffectedbythebatteryvoltage.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual571
575CHAPTER30NuclearPhysicsPracticeProblems30.1TheNucleuspages799–805page8011.Threeisotopesofuraniumhavemassnumbersof234,235,and238.Theatomicnumberofuraniumis92.Howmanyneutronsareinthenucleiofeachoftheseisotopes?A�Z�neutrons234�92�142neutrons235�92�143neutrons238�92�146neutrons2.Anisotopeofoxygenhasamassnumberof15.Howmanyneutronsareinthenucleusofthisisotope?A�Z�15�8�7neutrons3.Howmanyneutronsareinthemercuryisotope20080Hg?A�Z�200�80�120neutrons4.Writethesymbolsforthethreeisotopesofhydrogenthathavezero,one,andtwoneutronsinthenucleus.1231H,1H,1Hpage805Usethesevaluestosolvethefollowingproblems:massofhydrogen�1.007825u,massofneutron�1.008665u,1u�931.49MeV.5.Thecarbonisotope126Chasamassof12.0000u.a.Calculateitsmassdefect.Massdefect�(isotopemass)�(massofprotonsandelectrons)�(massofneutrons)�12.000000u�(6)(1.007825u)�(6)(1.008665u)��0.098940ub.CalculateitsbindingenergyinMeV.Bindingenergy�(massdefect)(bindingenergyof1u)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(�0.098940u)(931.49MeV/u)��92.161MeVPhysics:PrinciplesandProblemsSolutionsManual573
576Chapter30continued6.Theisotopeofhydrogenthatcontainsoneprotonandoneneutroniscalleddeuterium.Themassoftheatomis2.014102u.a.Whatisitsmassdefect?Massdefect�(isotopemass)�(massofprotonandelectron)�(massofneutron)�2.014102u�1.007825u�1.008665u��0.002388ub.WhatisthebindingenergyofdeuteriuminMeV?Bindingenergy�(massdefect)(bindingenergyof1u)�(�0.002388u)(931.49MeV/u)��2.2244MeV7.Anitrogenisotope,157N,hassevenprotonsandeightneutrons.Ithasamassof15.010109u.a.Calculatethemassdefectofthisnucleus.Massdefect�(isotopemass)�(massofprotonsandelectrons)�(massofneutrons)�15.010109u�(7)(1.007825u)�(8)(1.008665u)��0.113986ub.Calculatethebindingenergyofthenucleus.Bindingenergy�(massdefect)(bindingenergyof1u)�(�0.113986u)(931.49MeV/u)��106.18MeV8.Anoxygenisotope,168O,hasanuclearmassof15.994915u.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Whatisthemassdefectofthisisotope?Massdefect�(isotopemass)�(massofprotonsandelectrons)�(massofneutrons)�15.994915u�(8)(1.007825u)�(8)(1.008665u)��0.137005ub.Whatisthebindingenergyofitsnucleus?Bindingenergy�(massdefect)(bindingenergyof1u)�(�0.137005u)(931.49MeV/u)��127.62MeVSectionReview30.1TheNucleuspages799–805page8059.NucleiConsiderthesetwopairsofnuclei:121311116Cand6Cand5Band6C.Inwhichwayarethetwoalike?Inwhichwayaretheydifferent?574SolutionsManualPhysics:PrinciplesandProblems
577Chapter30continuedThefirstpairhasthesamenumberofprotons,butadifferentnumberofnucleons.Thesecondpairhasthesamenumberofnucleons,butadiffer-entnumberofprotons.10.BindingEnergyWhentritium,31H,decays,itemitsabetaparticleandbecomes32He.Whichnucleuswouldyouexpecttohaveamorenegativebindingenergy?Thetritiumnucleus,becausetritiumemitsaparticlewithmassandkinet-icenergyinitsdecay.11.StrongNuclearForceTherangeofthestrongnuclearforceissoshortthatonlynucleonsthatareadjacenttoeachotherareaffectedbytheforce.Usethisfacttoexplainwhy,inlargenuclei,therepulsiveelectromagneticforcecanovercomethestrongattractiveforceandmakethenucleusunstable.Theelectricforceislongrange,sothatallprotonsrepeleachother,eveninlargenuclei.Thestrongforceisshortrange,sothatonlyneighboringprotonsattract.Therepulsiveforcegrows,withincreasingnuclearsize,fasterthanthestrongforce.12.MassDefectWhichofthetwonucleiinproblem10hasthelargermassdefect?thetritiumnucleus13.MassDefectandBindingEnergyTheradioactivecarbonisotope146Chasamassof14.003074u.a.Whatisthemassdefectofthisisotope?Massdefect�(isotopemass)�(massofprotonsandelectrons)�(massofneutrons)�14.003074u�(6)(1.007825u)�(8)(1.008665u)��0.113169ub.Whatisthebindingenergyofitsnucleus?Bindingenergy�(massdefect)(bindingenergyof1u)�(�0.113196u)(931.49MeV/u)��105.44MeV14.CriticalThinkingInoldstars,notonlyareheliumandcarbonproducedbyjoiningmoretightlyboundnuclei,butsoareoxygen(Z�8)andsilicon(Z�14).Whatistheatomicnumberoftheheaviestnucleusthatcouldbeformedinthisway?Explain.26,iron,becauseitsbindingenergyislargest.PracticeProblemsCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.30.2NuclearDecayandReactionspages806–814page80815.Writethenuclearequationforthetransmutationofaradioactiveuraniumisotope,23423092U,intoathoriumisotope,90Th,bytheemissionofan�particle.234230492U®90Th�2HePhysics:PrinciplesandProblemsSolutionsManual575
578Chapter30continued16.Writethenuclearequationforthetransmu-21.Writethenuclearequationforthetransmu-tationofaradioactivethoriumisotope,tationofaseaborgiumisotope,263106Sg,into230arutherfordiumisotope,25990Th,intoaradioactiveradiumisotope,104Rf,bytheemis-226sionofanalphaparticle.88Ra,bytheemissionofan�particle.26325942302264106Sg®104Rf�2He90Th®88Ra�2He22.Aprotoncollideswiththenitrogenisotope17.Writethenuclearequationforthetransmu-15tationofaradioactiveradiumisotope,7N,forminganewisotopeandanalphaparticle.Whatistheisotope?Writethe22622288Ra,intoaradonisotope,86Rn,by�decay.nuclearequation.2262224151AX�488Ra®86Rn�2He7N�1H®Z2HewhereZ�7�1�2�618.Aradioactiveleadisotope,21482Pb,canA�15�1�4�12changetoaradioactivebismuthisotope,214ForZ�6,theelementmustbecarbon.83Bi,bytheemissionofa�particleandanThus,theequationisantineutrino.Writethenuclearequation.1511247N�1H®6C�2He.2142140e�082Pb®83Bi��10��23.Writethenuclearequationsforthebeta19.Aradioactivecarbonisotope,14decayofthefollowingisotopes.6C,under-goes�decaytobecomethenitrogena.2101480Pbisotope7N.Writethenuclearequation.210AX�0e�080Pb®Z�10��14140e�06C®7N��10��whereZ�80�(�1)�0�81A�210�0�0�210.page809ForZ�81,theelementmustbe20.Usetheperiodictableonpage916tocom-thallium.Thus,theequationispletethefollowing.2102100e�080Pb®81Tl��10��.a.140e�0Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.6C®?��10��b.21083Bi14AX�0e�06C®Z�10��210AX�0e�0whereZ�6�(�1)�0�783Bi®Z�10��whereZ�83�(�1)�0�84A�14�0�0�14A�210�0�0�210ForZ�7,theelementmustbe14ForZ�84,theelementmustbenitrogen.Thus,theisotopeis7N.polonium.Thus,theequationisb.550e�02102100e�024Cr®?��10��83Bi®84Po��10��.550e�0c.23424Cr®?��10��90Th234AX�0e�055AX�0e�090Th®Z�10��24Cr®Z�10��whereZ�90�(�1)�0�91whereZ�24�(�1)�0�25A�234�0�0�234A�55�0�0�55ForZ�91,theelementmustbeForZ�25,theelementmustbeprotactinium.Thus,theequationismanganese.Thus,theisotopeis552342340e�025Mn.90Th®91Pa��10��.576SolutionsManualPhysics:PrinciplesandProblems
579Chapter30continuedd.23927.Tritium,393Np1H,oncewasusedinsomewatches239AX�0e�0toproduceafluorescentglowsothatthe93Np®Z�10��watchescouldbereadinthedark.IfthewhereZ�93�(�1)�0�94brightnessoftheglowisproportionaltoA�239�0�0�239theactivityofthetritium,whatwouldbeForZ�94,theelementmustbethebrightnessofsuchawatch,incompari-plutonium.Thus,theequationissontoitsoriginalbrightness,whenthe2392390e�0watchissixyearsold?93Np®94Pu��10��.Sixyearsisabouthalfoftritium’shalf-lifeof12.3years.Thus,thepage8101�17brightnessis����2,orabout��oftheRefertoFigure30-4andTable30-2tosolvethe210originalbrightness.followingproblems.24.Asampleof1.0goftritium,31H,ispro-duced.WhatwillbethemassofthetritiumSectionReviewremainingafter24.6years?24.6years�(2)(12.3years),whichis30.2NuclearDecayand2half-lives.Reactions1tremaining�original����pages806–8142page81412�(1.0g)����28.BetaDecayHowcananelectronbe2expelledfromanucleusinbetadecayifthe�0.25gnucleushasnoelectrons?25.Theisotope238Inthenucleusaneutronchangesintoa93Nphasahalf-lifeof2.0days.If4.0gofneptuniumisproducedprotonandemitsanelectronandanonMonday,whatwillbethemassofantineutrino.neptuniumremainingonTuesdayofthe29.NuclearReactionsThepoloniumisotopenextweek?2108.0days�(4)(2.0days),whichis84Poundergoesalphadecay.Writetheequationforthereaction.4half-livesremaining210AX�484Po®Z2He1t�(original)����whereZ�84�2�82214A�210�4�206�(4.0g)����2ForZ�82,theelementmustbelead.�0.25gThus,theequationis210206484Po®82Pb�2He.26.Asampleofpolonium-210ispurchasedforaphysicsclassonSeptember1.Itsactivityis30.Half-LifeUseFigure30-4andTable30-2to2�106Bq.Thesampleisusedinanexperi-estimateinhowmanydaysasampleof13153ImentonJune1.Whatactivitycanbewouldhavethree-eighthsitsoriginalactivity.expected?Fromthegraph,3/8areleftataboutThehalf-lifeof21084Pois138days.1.4halflives.Fromthetable,thehalf-Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thereare273daysorabout2half-liveslifeis8.07days,soitwouldtakeaboutbetweenSeptember1andJune1.11days.Sotheactivity6decays12��2�10�������s2�5�105BqPhysics:PrinciplesandProblemsSolutionsManual577
580Chapter30continued31.NuclearReactorLeadoftenisusedasaradiationshield.Whyisitnotagoodchoiceforamoderatorinanuclearreactor?Leadisusedasaradiationshieldbecauseitabsorbsradiation,includingneutrons.Amoderatorshouldonlyslowtheneutronssotheycanbeabsorbedbythefissilematerial.32.FusionOnefusionreactioninvolvestwodeuteriumnuclei,21H.Adeuteriummoleculecontainstwodeuteriumatoms.Whydoesn’tthismoleculeundergofusion?Thenucleiinthemoleculemustbemovingveryfasttoundergofusion.33.EnergyCalculatetheenergyreleasedinthefirstfusionreactionintheSun,1120e�01H�1H®1H��10.TheenergyreleasedisE�((initialmass)�(finalmass))(931.49MeV/u)�(2(massofprotium)�(massofdeuterium)�(massofpositron))(931.49MeV/u)��2(1.007825u)�2.014102u�(9.11�10�31kg)�����1u�1.6605�10�27kg(931.49MeV/u)�0.931MeV34.CriticalThinkingAlphaemittersareusedinsmokedetectors.Anemitterismountedononeplateofacapacitor,andthe�particlesstriketheotherplate.Asaresult,thereisapotentialdifferenceacrosstheplates.Explainandpredictwhichplatehasthemorepositivepotential.Theplatebeingstuckbythe�particleshasthemorepositivepotentialbecausethepositivelycharged�particlesmovepositivechargefromtheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.emitterplatetothestruckplate.PracticeProblems30.3TheBuildingBlocksofMatterpages815–823page82135.Themassofaprotonis1.67�10�27kg.a.Findtheenergyequivalentoftheproton’smassinjoules.E�mc2�(1.67�10�27kg)(3.00�108m/s)2�1.50�10�10Jb.ConvertthisvaluetoeV.1.50�10�10JE����1.60217�10�19J/eV�9.36�108eV578SolutionsManualPhysics:PrinciplesandProblems
581Chapter30continuedc.Findthesmallesttotal-rayenergythatcouldresultinaproton-antiprotonpair.Theminimumenergyis(2)(9.36�108eV)�1.87�109eV36.Apositronandanelectroncanannihilateandformthreegammas.Twogammasaredetected.Onehasanenergyof225keV,theother357keV.Whatistheenergyofthethirdgamma?Asshowninthissection,theenergyequivalentofthepositronandelec-tronis1.02MeV.Thus,theenergyofthethirdgammais1.02MeV�0.225MeV�0.357MeV�0.438MeV.37.Themassofaneutronis1.008665u.a.Findtheenergyequivalentoftheneutron’smassinMeV.E�(neutronmassinu)(931.49MeV/u)�(1.008665u)(931.49MeV/u)�939.56MeVb.Findthesmallesttotal-rayenergythatcouldresultintheproductionofaneutron-antineutronpair.Thesmallestpossible�-rayenergywouldbetwicetheneutronenergy.Etotal�2En�(2)(939.56MeV)�1879.1MeV38.Themassofamuonis0.1135u.Itdecaysintoanelectronandtwoneutrinos.Whatistheenergyreleasedinthisdecay?Energyreleased�(massofmuon�massofelectron)(931.49MeV/u)���31kg)���1u0.1135u�(9.109�10��1.6605�10�27kg�(931.49MeV/u)�105.2MeVSectionReview30.3TheBuildingBlocksofMatterpages815–823page82339.NucleusBombardmentWhywouldaprotonrequiremoreenergythananeu-tronwhenusedtobombardanucleus?Theprotonandnucleusbothhavepositivecharge,sotheyrepeleachother.Therefore,theprotonmusthaveenoughkineticenergytoovercomethepotentialenergycausedbytherepulsion.TheunchargedneutrondoesCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.notexperiencethisrepulsiveforce.40.ParticleAcceleratorProtonsintheFermiLaboratoryaccelerator,Figure30-11,movecounterclockwise.Inwhatdirectionisthemagneticfieldofthebendingmagnets?down,intoEarthPhysics:PrinciplesandProblemsSolutionsManual579
582Chapter30continued41.PairProductionFigure30-18showstheChapterAssessmentproductionoftwoelectron/positronpairs.WhydoesthebottomsetoftrackscurvelessConceptMappingthanthetoppairoftracks?page828Theelectron/positronpairatthebottom44.Organizethefollowingtermsintothehasmorekineticenergy,andtherefore,conceptmap:StandardModel,quarks,agreatervelocity.gammarays,forcecarriers,protons,neutrons,leptons,Wbosons,neutrinos,electrons,gluons.42.TheStandardModelResearchthelimita-tionsoftheStandardModelandpossibleStandardreplacements.ModelAnswersinclude:TheStandardModelhasseveralparametersthatcanbeIncludesobtainedonlyfromexperiment.TheforceHiggsparticlethatwouldsettheenergyquarksleptonscarriersscalehasnotbeenfound.Itisnotreallyatheorythatexplains,andsoisnotWhichExamplesExamplescomposecomplete.Supersymmetryandstringgammatheoryaretwopossiblereplacements.protonselectronsraysgluons43.CriticalThinkingConsiderthefollowingneutronsneutrinosWbosonsequations.u®d�W�andW�®e��HowcouldtheybeusedtoexplaintheMasteringConceptsradioactivedecayofanucleonthatresultspage828intheemissionofapositronandaneutri-45.Whatforceinsideanucleusactstopushtheno?Writetheequationinvolvingnucleonsnucleusapart?Whatforceinsidethenucle-ratherthanquarks.usactstoholdthenucleustogether?(30.1)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.AnucleoncontainingauquarkcouldTherepulsiveelectricforcebetweenthedecaybythisprocesstoanucleonwithpositiveprotonsactstopushthenucle-onelessuandonemoredquark.Ausapart.Thestrongnuclearforceactsprotonisuudandaneutronisuud,sotoholdthenucleustogether.thefollowingequationwouldwork:110046.Definethemassdefectofanucleus.To1p®0n��1e�0�whatisitrelated?(30.1)Themassdefectisthedifferencebetweenthesumofthemassesoftheindividualparticlesofthenucleusandthemassofthenucleus.ItisrelatedtobindingenergythroughE�mc2.47.Whicharegenerallymoreunstable,smallorlargenuclei?(30.1)Largenucleiaregenerallymoreunstable.Thegreaternumberofprotonsmakestherepulsiveelectricforceovercometheattractivestrongforce.580SolutionsManualPhysics:PrinciplesandProblems
583Chapter30continued48.Whichisotopehasthegreaternumberofpro-fuseintoalargernucleus,themassoftons,uranium-235oruranium-238?(30.1)themoretightlybound,largenucleusisTheybothhavethesamenumberofpro-less,andtheextramassappearsastons,butdifferentnumbersofneutrons.energy.49.Definethetermtransmutationasusedin55.High-EnergyPhysicsWhywouldalinearnuclearphysicsandgiveanexample.(30.2)acceleratornotworkwithaneutron?(30.3)Transmutationisthechangeofoneele-Itacceleratesparticlesusingelectricmentintoanotherbymeansofaforce,andtheneutronhasnocharge.nuclearreactioncausedbyradioactive56.ForcesInwhichofthefourinteractionsdecayornuclearbombardment.For(strong,weak,electromagnetic,andgravita-example,uranium-238decaysintothori-tional)dothefollowingparticlestakepart?um-234andan�particle.(30.3)50.RadiationWhatarethecommonnamesa.electronforan�particle,�particle,andradiation?electromagnetic,weak,gravitational(30.2)b.protonAnaparticleisaheliumnucleus,astrong,electromagnetic,gravitational�particleisanelectron,and�radiationc.neutrinoisahigh-energyphoton.weak51.Whattwoquantitiesmustalwaysbecon-servedinanynuclearequation?(30.2)57.Whathappenstotheatomicnumberandmassnumberofanucleusthatemitsatheatomicnumber,toconservecharge;positron?(30.3)themassnumber,toconservethenum-berofnucleonsTheatomicnumberdecreasesby1,andthereisnochangeinthemassnumber.52.NuclearPowerWhatsequenceofeventsZ®Z�1;A®Amustoccurforachainreactiontotakeplace?(30.2)58.AntimatterWhatwouldhappenifamete-Manyneutronsmustbereleasedbyafis-oritemadeofantiprotons,antineutrons,sionednucleusandabsorbedbyneigh-andpositronslandedonEarth?(30.3)boringnuclei,causingthemtoundergoItwouldannihilatewithanequivalentfission.amountofmatter,producinganextremelylargeamountofenergy.53.NuclearPowerWhatroledoesamodera-torplayinafissionreactor?(30.2)ApplyingConceptsThemoderatorslowsthefastneutrons,page828increasingtheirprobabilityofbeing59.FissionAWebsiteclaimsthatscientistsabsorbed.havebeenabletocauseironnucleitoundergofission.Istheclaimlikelytobe54.Fissionandfusionareoppositeprocesses.true?Explain.Howcaneachreleaseenergy?(30.2)Itisnottrue.IronisthemosttightlyCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Whenalargeatom,suchasuranium,boundelement,andthusthemoststa-undergoesfission,themassoftheblenucleus.Itcannotdecaybyeitherproductsislessthanthatoftheoriginalfissionorfusion.nucleus.Anamountofenergyequiva-lenttothedifferenceinmassisreleased.However,whensmallnucleiPhysics:PrinciplesandProblemsSolutionsManual581
584Chapter30continued60.UsethegraphofbindingenergypernucleoninFigure30-2todeterminewhetherthereaction2131H�1H®2Heisenergeticallypossible.Theinitialbindingenergyislessthanthefinalbindingenergyand,there-fore,thereactionisenergeticallypossible.61.IsotopesExplainthedifferencebetweennaturallyandartificiallyproducedradioactiveisotopes.Anaturalradioactivematerialisonethatisfoundtoexistnormallyinoresandthatexperiencesradioactivedecay.Artificially,radioactivematerialexperiencesradioactivedecayonlyafterbeingsubjectedtobombardmentbyparticles.62.NuclearReactorInanuclearreactor,waterthatpassesthroughthecoreofthereactorflowsthroughoneloop,whilethewaterthatproducessteamfortheturbinesflowsthroughasecondloop.Whyaretheretwoloops?Thewaterthatpassesthroughthecoreisathighpressure,soitdoesn’tboil.Asecondloopcarrieswateratlowerpressure,producingsteam.63.Thefissionofauraniumnucleusandthefusionoffourhydrogennucleitopro-duceaheliumnucleusbothproduceenergy.a.Whichproducesmoreenergy?AsshowninSection30-2,theenergyproducedbythefissionofoneuraniumnucleusis200MeV.Theenergyproducedbythefusionoffourhydrogennucleiis24MeV.b.Doesthefissionofakilogramofuraniumnucleiorthefusionofakilogramofhydrogenproducemoreenergy?Themassnumberoffissionableuraniumis238.ThemassnumberCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofhydrogenis1.Foranequalmassoftheelements,youwouldhave238timesmorehydrogennucleithanuraniumnuclei.Thefissionofeachuraniumnucleuswouldproduce200MeVofenergy.Thefusionof238nucleiofhydrogentoproduceheliumnucleiwouldproduce238����(25MeV),orabout1500MeVofenergy.4c.Whyareyouranswerstopartsaandbdifferent?Althoughthefissionofoneuraniumnucleusproducesmoreenergythanthefusionoffourhydrogennucleitoproducehelium,therearemorethan200timesasmanyhydrogennucleiin1kgasthereareura-niumnuclei.MasteringProblems30.1TheNucleuspages828–829Level164.Whatparticles,andhowmanyofeach,makeupanatomof10947Ag?47electrons,47protons,62neutrons582SolutionsManualPhysics:PrinciplesandProblems
585Chapter30continued65.Whatistheisotopicsymbol(theoneusedinnuclearequations)ofazincatomcomposedof30protonsand34neutrons?6430Zn66.Thesulfurisotope3216Shasanuclearmassof31.97207u.a.Whatisthemassdefectofthisisotope?massdefect�(isotopemass)�(massofprotonsandelectrons)�(massofneutrons)�31.97207u�(16)(1.007825u)�(16)(1.008665u)��0.29177ub.Whatisthebindingenergyofitsnucleus?Bindingenergy�(massdefect)(bindingenergyof1u)�(�0.29177u)(931.5MeV/u)��271.78MeVc.Whatisthebindingenergypernucleon?Bindingenergypernucleonis�271.8MeV����8.494MeV/nucleon32nucleonsLevel267.Anitrogenisotope,127N,hasanuclearmassof12.0188u.a.Whatisthebindingenergypernucleon?Bindingenergy�(massofdefect)(bindingenergyfor1u)((isotopemass)�(massofprotonsandelectrons)�(massofneutrons))(bindingenergyfor1u)�((12.0188u)�(7)(1.007825u)�(5)(1.008665u))(931.49MeV/u)��73.867MeV�73.867MeVThebindingenergypernucleonis����6.1556MeV/nucleon12nucleonsb.Doesitrequiremoreenergytoseparateanucleonfroma147Nnucleusorfroma12147Nnucleus?7Nhasamassof14.00307u.For147N,thebindingenergyisBindingenergy�(massdefect)(bindingenergyfor1u)�((isotopemass)�(massofprotonsandelectrons)�(massofneutrons))(bindingenergyfor1u)�((14.00307u�(7)(1.007825u)�(7)(1.008665u))(931.49MeV/u)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��104.66MeV�104.66MeVThebindingenergypernucleonis����7.4757MeV/nucleon14nucleonsThus,removinganucleonfrom147Nrequiresmoreenergy.Physics:PrinciplesandProblemsSolutionsManual583
586Chapter30continued68.Thetwopositivelychargedprotonsinaheliumnucleusareseparatedbyabout2.0�10�15m.UseCoulomb’slawtofindtheelectricforceofrepulsionbetweenthetwoprotons.Theresultwillgiveyouanindicationofthestrengthofthestrongnuclearforce.qAqBF�K�2d(1.60�10�19C)(1.60�10�19C)�(9.0�109N�m2/C2)�����58N2.0�10�15m69.Thebindingenergyfor42Heis�28.3MeV.Calculatethemassofaheliumiso-topeinatomicmassunits.massoftheisotope�(massdefect)�(massofprotonsandelectrons)�(massofneutrons)bindingenergy�������bindingenergyof1u(massofprotonsandelectrons)�(massofneutrons)�28.3MeV������(2)(1.007825u)�(2)(1.008665u)931.49MeV/u�4.00u30.2NuclearDecayandReactionspage829Level170.Writethecompletenuclearequationforthealphadecayof22286Rn.222AX�486Rn®Z2HeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.whereA�222-4�218Z�86-2�84ForZ�84,theelementmustbepolonium.Thus,theequationis222218486Rn®84Po�2He71.Writethecompletenuclearequationforthebetadecayof8936Kr.89AX�0e�036Kr�Z�10��whereZ�36�(�1)�0�37A�89�0�0�89ForZ�37,theelementmustberubidium.Thus,theequationis89890e�036Kr�37Rb1��10��72.Completeeachnuclearreaction.a.225489Ac®2He�_____225422189Ac®2He�87Frb.2270e�_____�_____88Ra®�12270e�227088Ra®�189Ac�0��584SolutionsManualPhysics:PrinciplesandProblems
587Chapter30continuedc.651175.Whenaboronisotope,1129Cu�0n®_____®1p�_____5B,isbombardedwithprotons,itabsorbsaprotonandemits6516616529Cu�0n®29Cu®1p�28Nianeutron.d.2351961a.Whatelementisformed?92U�0n®40Zr�3(0n)�_____2351961136carbon92U�0n®40Zr�3�0n��52Teb.Writethenuclearequationforthis73.Anisotopehasahalf-lifeof3.0days.Whatreaction.percentoftheoriginalmaterialwillbeleftafter111A15B�1p®6C�0na.6.0days?whereA�11�1�1�11�6.0�d�2.0half-livesThus,theequationis3.0d1111111t5B�1p®6C�0npercentremaining������1002c.Theisotopeformedisradioactiveand12.0decaysbyemittingapositron.Write������1002thecompletenuclearequationforthis�25%reaction.b.9.0days?11A0e�06C®ZX��10��9.0d���3.0half-liveswhereZ�6�1�0�53.0dA�11�0�0�111tpercentremaining������100ForZ�5,theelementmustbe2boron.Thus,theequationis13.0���2���10011110e�06C®5B��10���13%76.Thefirstatomicbombreleasedanenergyc.12days?equivalentof2.0�101kilotonsofTNT.One�12d�4half-lives12J.kilotonofTNTisequivalentto5.0�103.0dUranium-235releases3.21�10�11J/atom.percentremaining��1�t�100Whatwasthemassoftheuranium-235that��2underwentfissiontoproducetheenergyof14.0thebomb?������1002E�(2.0�101kton)(5.0�1012J/kton)�6.3%1atom1mol����3.21�10�11J����6.02�1023atom74.Inanaccidentinaresearchlaboratory,aradioactiveisotopewithahalf-lifeofthree0.235kg����daysisspilled.Asaresult,theradiationismoleighttimesthemaximumpermissible�1.2kgamount.Howlongmustworkerswaitbeforetheycanentertheroom?77.Duringafusionreaction,twodeuterons,12Fortheactivitytofallto��itspresent1H,combinetoformaheliumisotope,83amount,youmustwaitthreehalf-lives,2He.Whatotherparticleisproduced?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.or9days.223A1H�1H®2He�ZXwhereZ�1�1�2�0A�2�2�3�1Thus,theparticlemustbe10n,aneutron.Physics:PrinciplesandProblemsSolutionsManual585
588Chapter30continuedLevel2b.du�78.2091284Pohasahalf-lifeof103years.Howlongd��u���������������1chargewouldittakefora100-gsampletodecayso33c.dd�thatonly3.1gofPo-209wasleft?111tu��d��������������0chargeremaining�original����332LetR�remainingmassandI�origi-82.Baryonsareparticlesthataremadeofthreenalmassquarks.Findthechargeoneachofthefol-1tIlowingbaryons.R�I��2�����t2a.neutron:ddut�I122�R�d�d�u�2�����������033log(2t)�log��I��b.antiproton:u�u�d�R221Iu���u��d����3������3�������3��tlog2�log����R��1Ilog����Rt��Level2log283.ThesynchrotronattheFermiLaboratory100glog��3.1�g�hasadiameterof2.0km.Protonscircling���initmoveatapproximatelythespeedoflog2lightinavacuum.�5half-livesa.Howlongdoesittakeaprotontocom-Therefore,thesamplewouldtakeaboutpleteonerevolution?500yearstodecay.dv���t30.3TheBuildingBlocksofMatterwheredisthecircumferenceofthepage829synchrotron,Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Level1d�(2.0�103m)79.Whatwouldbethechargeofaparticlesot��v����8m/s3.0�10composedofthreeupquarks?�2.1�10�5s2Eachuquarkhasachargeof���.3b.Theprotonsentertheringatanenergy2of8.0GeV.Theygain2.5MeVeachuuu�3�������2elementarychargesrevolution.Howmanyrevolutionsmust3theytravelbeforetheyreach400.0GeV80.Thechargeofanantiquarkisoppositethatofenergy?ofaquark.Apioniscomposedofanupquarkandananti-downquark,ud�.What400.0�109eV�8.00�109eV����2.5�106eV/revwouldbethechargeofthispion?�1.6�105rev21u��d��������������1elementary33c.Howlongdoesittaketheprotonstobechargeacceleratedto400.0GeV?81.Pionsarecomposedofaquarkandananti-t�(1.6�105rev)(2.1�10�5s/rev)quark.Findthechargeofapionmadeup�3.4softhefollowing.d.Howfardotheprotonstravelduringa.uu�thisacceleration?22d��u��������������0charged�vt�(3.00�108m/s)(3.4s)33�1.0�109m,orabout1millionkm586SolutionsManualPhysics:PrinciplesandProblems
589Chapter30continued84.Figure30-21showstracksinabubbleLevel2chamber.Whataresomereasonsonetrack87.Oneofthesimplestfusionreactionsmightcurvemorethananother?involvestheproductionofdeuterium,21H(2.014102u),fromaneutronandapro-ton.Writethecompletefusionreactionandfindtheamountofenergyreleased.Theequationforthereactionis1120n�0p®1HTheenergyreleasedisE�((initialmass)�(finalmass))(931.49MeV/u)�((massofneutron)�(massofproton)�(massofdeuterium))(931.49MeV/u)■Figure30-21�((1.008665u)�(1.007276u)�Thepathsoffaster-movingparticles(2.014102u))(931.49MeV/u)wouldcurveless.�1.7130MeVMixedReview88.A232page83092Unucleus,mass�232.0372u,decaysto228Level190Th,mass�228.0287u,byemittingan�particle,mass�4.0026u,witha85.Eachofthefollowingnucleicanabsorbankineticenergyof5.3MeV.Whatmustbe�particle.Assumethatnosecondaryparti-thekineticenergyoftherecoilingthoriumclesareemittedbythenucleus.Completenucleus?eachequation.a.144Thetotalkineticenergyofthedecay7N�2He®_____productsis144AX7N�2He®ZKEtotal�KEthorium�KE�whereZ�7�2�9Thus,A�14�4�18KEthorium�KEtotal�KE�ForZ�9,theelementmustbe�(massdefect)fluorine.Thus,theequationis(931.49MeV/u)�KE14418�7N�2He®9F�((massof23292U)�b.274(massof22813Al�2He®_____90Th)�(massof4274A2He))13Al�2He®ZX(931.49MeV/u)�KEwhereZ�13�2�15��((232.0372u)�(228.0287u)�A�27�4�31(4.0026u))ForZ�15,theelementmustbe(931.49MeV/u)�5.3MeVphosphorus.Thus,theequationis�0.2MeV27431Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.13Al�2He®15P86.21186Rnhasahalf-lifeof15h.Whatfractionofasamplewouldbeleftafter60h?60h141���4half-lives,so�������isleft.15h216Physics:PrinciplesandProblemsSolutionsManual587
590Chapter30continuedThinkingCriticallynumberofreactionsoccurringeachsecondispage8304�1026J/s89.InferGammarayscarrymomentum.The����1038reactions/s4.0�10�12J/reactionmomentumofagammarayofenergyEisequaltoE/c,wherecisthespeedoflight.92.InterpretDataAnisotopeundergoingWhenanelectron-positronpairdecaysintoradioactivedecayismonitoredbyaradia-twogammarays,bothmomentumandtiondetector.Thenumberofcountsineachenergymustbeconserved.Thesumofthefive-minuteintervalisrecorded.Theresultsenergiesofthegammaraysis1.02MeV.IfareshowninTable30-3.Thesampleisthepositronandelectronareinitiallyatrest,thenremovedandtheradiationdetectorwhatmustbethemagnitudeanddirectionrecords20countsresultingfromcosmicofthemomentumofthetwogammarays?raysin5min.Findthehalf-lifeoftheBecausetheinitialmomentumiszero,isotope.Notethatyoushouldfirstsubtractthismustbethefinalmomentum.Thus,the20-countbackgroundreadingfromeachthetwogammaraysmusthaveequalresult.Thenplotthecountsasafunctionandoppositemomentum.Themagni-oftime.Fromyourgraph,determinethetudeofthemomentaishalf-life.1Ep����2����C��Table30-3(1.02�106eV)(1.60�10�19J/eV)RadioactiveDecay�����(2)(3.00�108m/s)Measurements�2.72�10�22kg�m/sTime(min)Counts(per5min)Theymoveinoppositedirections.098790.InferAnelectron-positronpair,initiallyat5375rest,alsocandecayintothreegammarays.10150Ifallthreegammarayshaveequalenergies,1570Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.whatmustbetheirrelativedirections?Make2040asketch.2525Thequestionbecomesthefollowing:3018howcanthreeparticles,eachwiththesamemomentum,havezerototalabout4minmomentum?Thethreegammaraysleavewithanglesof120°betweenthemWritinginPhysicsonaplane.page83093.Researchthepresentunderstandingofdark91.EstimateOnefusionreactionintheSunmatterintheuniverse.Whyisitneededbyreleasesabout25MeVofenergy.Estimatecosmologists?Ofwhatmightitbemade?thenumberofsuchreactionsthatoccurAbout25percentoftheuniverseisdarkeachsecondfromtheluminosityofthematter.ItisneededtoexplaingalacticSun,whichistherateatwhichitreleasesenergy,4�1026W.rotationandtheexpansionoftheuni-verse.Accordingtoonetheory,dark1eV�1.6022�10�19J,somatterisnotmadeofordinarymatter25MeV�(25�106eV/reaction)thatiscoveredbytheStandardModel.(1.6022�10�19J/eV)Itmayinteractwithordinarymatteronly�4.0�10�12J/reactionthroughgravityandweaknuclearThetotalpoweris4�1026J/s,sotheforces.588SolutionsManualPhysics:PrinciplesandProblems
591Chapter30continued94.Researchthehuntforthetopquark.Whyb.CalculatetheenergyoftheelectronineV.didphysicistshypothesizeitsexistence?12KE���mvTheoristshadpredictedtheexistence2ofdifferentflavorsofquarks.Theyreal-���1��(9.11�10�31kg)(1.82�103m/s)2izedquarksoccurinpairs.Theupand2downquarkpairandthecharmedand1eVstrangepairhadbeenfoundbyexperi-����1.60�10�19Jments.Whenthebottomquarkwas�9.43�10�6eVfoundin1977,theyfeltitmusthaveapartner.Theshortlifetimeandhigh98.Aphotonwithanenergyof14.0eVentersamassofthetopquarkmadeitdifficulthydrogenatominthegroundstateandion-tofind.ItfinallywasfoundataFermilabizesit.Withwhatkineticenergywilltheexperimentin1995.electronbeejectedfromtheatom?(Chapter28)CumulativeReviewKE�(photonenergy)�(energyofpage830electroninthegroundstate)95.Anelectronwithavelocityof1.7�106m/s�14.0eV�(�13.6eV)isatrightanglestoa0.91-Tmagneticfield.Whatistheforceontheelectronproduced�0.4eVbythemagneticfield?(Chapter24)99.Asilicondiode(V�0.70V)thatiscon-F�Bqvducting137mAisinserieswitharesistor�(0.91T)(1.60�10�19C)anda6.67-Vpowersource.(Chapter29)(1.7�106m/s)a.Whatisthevoltagedropacrossthe�2.5�10�13Nresistor?V96.AnEMFof2.0mVisinducedinawirethatR�Vsource�Vdiodeis0.10mlongwhenitismovingperpen-�6.67V�0.70Vdicularlyacrossauniformmagneticfieldat�5.97Vavelocityof4.0m/s.Whatisthemagneticb.Whatisthevalueoftheresistor?inductionofthefield?(Chapter25)V5.97VEMF�BLvR�����137�mA�43.6�IEMF2.0�10�3VB�������Lv(0.10m)(4.0m/s)�5.0�10�3T�5.0mT97.AnelectronhasadeBrogliewavelengthof400.0nm,theshortestwavelengthofvisiblelight.(Chapter27)a.Findthevelocityoftheelectron.h����mvhv���Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.m�6.63�10�34J/Hz�����(9.11�10�31kg)(400.0�10�9m)�1.82�103m/sPhysics:PrinciplesandProblemsSolutionsManual589
592Chapter30continuedChallengeProblempage82123892Udecaysby�emissionandtwosuccessive�emissionsbackintouraniumagain.1.Showthethreenucleardecayequations.Forthe�emission,238AX�492U®Z2HewhereZ�92–2�90A�238�4�234ForZ�90,theelementmustbethorium.Thus,theequationis238234492U®90Th�2HeForthefirst�emission,234AX�0e�090Th®Z�10��whereZ�90�(�1)�0�91A�234�0�0�234ForZ�91,theelementmustbeprotactinium.Thus,theequationis2342340e�090Th®91Pa��10��Forthesecond�emission,234AX�0e�091Pa®Z�10��whereZ�91�(�1)�0�92A�234�0�0�234ForZ�92,theelementmustbeuranium.Thus,theequationis2342340e�091Pa®92U��10��2.Predicttheatomicmassnumberoftheuraniumformed.A�234Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.590SolutionsManualPhysics:PrinciplesandProblems
593AppendixBAdditionalProblemsChapter1........................593Chapter16.......................641Chapter2........................595Chapter17.......................642Chapter3........................598Chapter18.......................644Chapter4........................602Chapter19.......................646Chapter5........................607Chapter20.......................649Chapter6........................612Chapter21.......................651Chapter7........................616Chapter22.......................655Chapter8........................618Chapter23.......................658Chapter9........................622Chapter24.......................662Chapter10.......................626Chapter25.......................664Chapter11.......................628Chapter26.......................665Chapter12.......................631Chapter27.......................669Chapter13.......................635Chapter28.......................672Chapter14.......................638Chapter29.......................674Chapter15.......................640Chapter30.......................677
594AppendixBfolicacid:Chapter1(400mcg)(0.001mg/mcg)�0.4mgpage858vitaminB12:1.Thedensity,�,ofanobjectisgivenbythe(6mcg)(0.001mg/mcg)�0.006mgratiooftheobject’smass,m,andvolume,V,biotin:accordingtotheequation��m/V.Whatis(30mcg)(0.001mg/mcg)�0.03mgthedensityofacubethatis1.2cmoneachsideandhasamassof25.6g?6.Whattypeofrelationshipisshowninthem25.6g3scatterplot?Writeanequationtomodel������3�15g/cmV(1.2cm)thedata.2.Anobjectthatismovinginastraightlinewithspeedvcoversadistance,d�vt,in1.2timet.Rewritetheequationtofindtintermsofdandv.Howlongdoesittake1.0aplanethatistravelingat350km/hto0.8travel1750km?0.6d1750kmt������5.0hv350km/h0.43.Convert523kgtomilligrams.0.21000g1000mg523kg�(523kg)��������01kg1g123456�5.23�108mg1.2inverserelationship;y��x4.Theliquidmeasuremilliliter,mL,isthesameas1cm3.Howmanymillilitersof7.Howmanysignificantdigitsarethereinliquidcanbeheldina2.5-m3container?eachofthefollowingmeasurements?3�(2.5m3)100cm31mL2.5m������3a.100m1m1cm1�2.5�106mLb.0.0023m/s5.Partofthelabelfromavitamincontainer2isshownbelow.Theabbreviation“mcg”c.100.1mstandsformicrograms.Convertthevalues4tomilligrams.d.2.00235EachTabletContains%DVCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.FolicAcid400mcg100%VitaminB126mcg100%Biotin30mcg10%Physics:PrinciplesandProblemsSolutionsManual593
595Chapter1continued8.Thebuoyant(upward)forceexertedbywaterb.Arethedatalinear?onasubmergedobjectisgivenbytheformulanoF��Vg,where�isthedensityofwaterc.Plottheperiodversusthesquarerootof(1.0�103kg/m3),Visthevolumeofthethelength.objectinm3,andgistheaccelerationduetogravity(9.80m/s2).Theforceisinnewtons.�I�TRewritetheequationtofindVintermsofF.0.30.6Usethistofindthevolumeofasubmerged0.40.9barrelifthebuoyantforceonitis9200N.0.61.3FV����g0.81.69200N30.91.8������0.94m(1.0�103kg/m3)(9.80m/s2)1.02.09.Whatis2.3kg�0.23g?2.3kg�0.23g�2.3�103g�0.23g2.0�2.3�103g�2.3kg10.Solvethefollowingproblems.1.0a.15.5cm�12.1cmPeriod(s)188cm20.00.20.40.60.81.014.678mb.��3.2m/s�l�m4.6sd.Whatistherelationshipbetweentheperiodandthesquarerootofthelength?11.AnexperimentwasperformedtodeterminetheperiodofapendulumasafunctionofThegraphislinear,sotheperiodisthelengthofitsstring.ThedatainthetableproportionaltothesquarerootofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.belowweremeasured.thelengthofthestring.Length(m)Period(s)12.Basedonthepreviousproblem,whatshould0.10.6betheperiodofapendulumwhoselengthis0.7m?0.20.9around1.7s0.41.30.61.60.81.81.02.0a.Plotperiod,T,versuslength,l.2.01.0Period(s)0.00.20.40.60.81.0Length(m)594SolutionsManualPhysics:PrinciplesandProblems
596a.WhatisthepositionofthecaratChapter20.00s?pages859–86040.0m1.Aposition-timegraphforabicycleisshownb.Whatisthepositionoftheautomobileinthefigurebelow.after2.00shaselapsed?40.020.0mc.Howfardidtheautomobiletravel30.0betweenthetimes1.00sand3.00s?distancetraveled�30.0m�10.0m20.0�20.0mPosition(m)10.03.Ajoggerrunsataconstantrateof10.0mevery2.0s.Thejoggerstartsattheorigin,and0.001.002.003.004.005.00runsinthepositivedirectionfor3600.0s.Time(min)Thefigurebelowisaposition-timegraphshowingthepositionofthejoggerfroma.Whatisthepositionofthebicycleattimet�0.0stotimet�20.0s.Whereis1.00min?therunnerattimet�5.0s?t�15.0s?35.0mb.Whatisthepositionofthebicycleat100.03.50min?35.0m75.0c.Whatisthedisplacementofthebicyclebetweenthetimes1.00min50.0and5.00min?Position(m)0.00m25.0d.Describethemotionofthebicycle.Thebicycleisnotmoving.0.04.08.012.016.020.02.ThepositionofanautomobileisplottedasaTime(s)functionoftimeintheaccompanyingfigure.Att�5.0sthejoggerisat25.0m.50.0Att�15.0sthejoggerisat75.0m.40.030.020.0Position(m)10.00.0Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1.002.003.004.005.00Time(s)Physics:PrinciplesandProblemsSolutionsManual595
597Chapter2continued4.Twotrainssimultaneouslyleavethesametrainstationatnoon.Onetraintravels2.0CarAnorthandtheothertravelssouth.Theposition-timegraphforbothtrainsis1.5CarBshownintheaccompanyingfigure.1.0North1000.0Position(km)0.50.01.02.03.04.05.00.0Time(h)Time(min)4.06.08.010.0Position(km)a.HowfarapartarethetwocarswhencarBstartsoutatt�1.0min?0.75kmb.Atwhattimedothecarsmeet?South�1000.02.0mina.Whatisthepositionofthetrainc.Howfarapartarethecarsattimetravelingnorthat6.0h?t�3.0min?600.0km0.75kmb.Whatisthepositionofthetraintravelingsouthat6.0h?6.Theposition-timegraphfortwojoggers,AandB,isshownintheaccompanyingfigure.300.0kmc.Whatisthedistancebetweenthetrains2.00at6.0h?Whatisthedistanceat10.0h?JoggerB900.0km,1500.0kmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1.50d.Atwhattimearethetrains600.0kmapart?1.004.0hPosition(km)e.Whichtrainismovingmorequickly?0.50JoggerAnorthboundtrain5.Twocarsheadoutinthesamedirection.0.0010.020.030.040.050.0CarAstarts1.0minbeforecarB.TheTime(min)position-timegraphsforbothcarsareshownintheaccompanyingfigure.a.Howfarapartarethetworunnersat10.0min?1.50kmb.Atwhattimearethey1.00kmapart?20.0minc.Howfarapartaretheyat50.0min?0.50kmd.Atwhattimedotheymeet?40.0min596SolutionsManualPhysics:PrinciplesandProblems
598Chapter2continuede.WhatdistancedoesjoggerBcovera.Whatistheaveragevelocityofthebetween30.0minand50.0min?airplane?0.00kmvelocity�slopeoflinef.WhatdistancedoesjoggerAcover�800.0km�0.0km����between30.0minand50.0min?5.0h�1.0h1.00km��2.0�102km/hb.Whatistheaveragespeedofthe7.Achild’stoytrainmovesataconstantairplane?speedof2.0cm/s.speed�absolutevalueofthevelocitya.Drawtheposition-timegraphshowing�2.0�102km/hthepositionofthetoyfor1.0min.9.Theposition-timegraphforahot-airballoonthatisinflightisshownin120theaccompanyingfigure.90Time(h)600.01.02.03.04.05.0Position(cm)300�10.0102030405060Time(s)�20.0b.Whatistheslopeofthelinerepresentingthemotionofthetoy?Position(km)�30.0rise120cmslope����run60s�2.0cm/s,thesameasthe�40.0train’sspeeda.Whatistheaveragevelocityofthe8.Thepositionofanairplaneasafunctionballoon?oftimeisshowninthefigurebelow.velocity�slopeTime(h)0.00km�(�40.0km)����5.0h�0.0h0.01.02.03.04.05.0�8.0km/hb.Whatistheaveragespeedofthe�200.0balloon?speed�absolutevalueofslope�400.0�8.0km/hPosition(km)�600.0�800.0Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual597
5993.Acartravelingat21m/smissestheturnoffonChapter3theroadandcollidesintothesafetyguardrail.pages861–862Thecarcomestoacompletestopin0.55s.1.Jasonandhissister,Tara,areridingbicycles.a.WhatistheaverageaccelerationofJasontriestocatchuptoTara,whohasathecar?10.0-sheadstart.v�vfi0.00m/s�21m/sa�������t�t0.55sfi8.0Jason��38m/s2Tarab.Ifthesafetyrailconsistedofasectionof6.0rigidrail,thecarwouldstopin0.15s.Whatwouldbetheaccelerationinthis4.0case?v�vVelocity(m/s)fi0.00m/s�21m/sa�������t�t0.15s2.0fi��1.4�102m/s20.010.020.030.040.04.Onthewaytoschool,JamalrealizesthatTime(s)helefthisphysicshomeworkathome.Hiscarwasinitiallyheadingnorthat24.0m/s.a.WhatisJason’sacceleration?Ittakeshim35.5stoturnhiscararound8.0m/s�0.0m/sandheadsouthat15.0m/s.Ifnorthisa���J�30.0s�10.0sdesignatedtobethepositivedirection,�0.40m/s2whatistheaverageaccelerationofthecarb.WhatisTara’sacceleration?duringthis35.5-sinterval?a���8.0m/s�0.0m/svf�vi�15.0m/s�24.0m/sT�40.0s�0.0sa��t��t����35.5sfi�0.20m/s2�1.10m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.Atwhattimedotheyhavethesamevelocity?5.Acheetahcanreachatopspeedof27.8m/sin5.2s.Whatisthecheetah’saverage20.0sacceleration?2.Adragsterstartsfromrestandacceleratesv�vfi27.8m/s�0.0m/sfor4.0satarateof5.0m/s2.Itthentravelsa�������t�t5.2sfiataconstantspeedfor2.5s.Aparachute�5.3m/s2opens,stoppingthevehicleataconstantratein2.0s.Plotthev-tgraphrepresenting6.Afterbeinglaunched,arocketattainsaspeedtheentiremotionofthedragster.of122m/sbeforethefuelinthemotoriscompletelyused.Ifyouassumethattheaccel-20.0erationoftherocketisconstantat32.2m/s2,15.0howmuchtimedoesittakeforthefueltobecompletelyconsumed?10.0�va���Velocity(m/s)5.0�t�v122m/s�0.00m/s0.0�t������2�3.79s2.04.06.08.010.0a32.2m/sTime(s)598SolutionsManualPhysics:PrinciplesandProblems
600Chapter3continued7.Anobjectinfreefallhasanaccelerationofc.Whatisthedisplacementoftherunner9.80m/s2assumingthatthereisnoairresis-betweent�50.0sandt�60.0s?tance.Whatisthespeedofanobjectdropped1�d����(8.0m/s)(60.0s�50.0s)fromthetopofatallcliff3.50safterithas2beenreleased,ifyouassumetheeffectofair�4.0�101mresistanceagainsttheobjectisnegligible?�v10.Drawthev-tgraphofanautomobilethata����tacceleratesuniformlyfromrestatt�0.00s�v�a�t�g�t�(9.80m/s2)(3.50s)andcoversadistanceof180.0min12.0s.�34.3m/sSincethecaracceleratesuniformly,thev-tgraphisastraightline.Startingfrom8.Atrainmovingwithavelocityof51m/seasttheorigin,theareaistriangular.undergoesanaccelerationof�2.3m/s2asit1Thus,�d��vapproachesatown.Whatisthevelocityofthe2max�ttrain5.2safterithasbeguntodecelerate?2�d(2)(180.0m)v������30.0m/svmax��t12.0s�vf�via������t�t30.0v�t�vf�ai�(�2.3m/s2)(5.2s)�51m/s�39m/s15.0Velocity(m/s)9.Thev-tgraphofarunnerisshownintheaccompanyingfigure.0.02.04.06.08.010.012.0Time(s)8.011.Thev-tgraphofacarisshownintheaccom-6.0panyingfigure.Whatisthedisplacementofthecarfromt�0.00stot�15.0s?4.030.0Velocity(m/s)2.015.00.0010.020.030.040.050.060.0Time(s)0.004.008.0012.0016.00ThedisplacementistheareaundertheTime(s)Velocity(m/s)graph.�15.0a.Whatisthedisplacementoftherunnerbetweent�0.00sandt�20.0s?�d����1�30.02(8.0m/s)(20.0s)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�8.0�101mdisplacement�areaunderv-tgraphb.WhatisthedisplacementoftherunnerThetotaldisplacementisthesumofbetweent�20.0sandt�50.0s?thedisplacementsfrom0.00sto4.00s,4.00sto6.00s,6.00sto8.00s,8.00sto�d�(8.0m/s)(50.0s�20.0s)10.0s,and10.0sto15.0s:�240mPhysics:PrinciplesandProblemsSolutionsManual599
601Chapter3continued�dtotal��d1��d2��d3��d4��d5vf�vi�1.23m/s�3.24m/st������f�a�2.32m/s21����(30.0m/s)(4.00s)��1.93s2(30.0m/s)(2.00s)�15.Acheetahcanacceleratefromresttoaspeed1of27.8m/sin5.20s.Thecheetahcanmain-���(30.0m/s)(2.00s)�2tainthisspeedfor9.70sbeforeitquickly1runsoutofenergyandstops.Whatdistance���(�30.0m/s)(2.00s)�2doesthecheetahcoverduringthis14.9-srun?(�30.0m/s)(5.00s)Duringtheaccelerationperiod:��30.0mvf�vi�atfvv12.Supposeacarrollsdowna52.0-m-longa�f��i����27.8m/s�0.00m/s�t5.20sinclinedparkinglotandisstoppedbyaffence.Ifittookthecar11.25storolldown�5.35m/s2thehill,whatwastheaccelerationoftheWiththisaccelerationthedistancecarbeforestrikingthefence?duringaccelerationcanbedetermined.12df�di�vitf��2atfv2�v2�2a(d�dfifi)vi�0.00m/ssincethecarstartsv2�v2fifromrestdf�di��2a�2(df�di)(2)(52.0m)2(27.8m/s)2�(0.00m/s)2a���t2���(11.25s)2�0.823m/s����(2)(5.35m/s2)f�72.3m13.AskydiverinfreefallreachesaspeedofDuringtheconstantspeedperiod,65.2m/swhensheopensherparachute.a�0.00m/s2.Theparachutequicklyslowsherdownto2.7.30m/sataconstantrateof29.4m/sCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.d�vt�(27.8m/s)(9.70s)Duringthisperiodofacceleration,howfar�2.70�102mdoesshefall?v2�v2�2a(d�dThetotaldistanceisthenthesumoffifi)thetwo.v2�v2distance�2.70�102m�72.3mfid�d��fi�2a�342m(�7.30m/s)2�(�65.2m/s)2�����(2)(29.4m/s2)16.Acabdriverinahurryissittingataredlight.��71.4mWhenthelightturnsgreensherapidlyaccel-eratesfor3.50sat6.80m/s2.ThenextlightShehasfallen71.4mduringtheaccel-isstillred.Shethenslamsonthebrakes,erationperiod.acceleratingatarateof�9.60m/s2beforecomingtorestatthestoplight.Whatwasher14.Achildrollsaballupahillat3.24m/s.totaldistanceforthistrip?Iftheballexperiencesanaccelerationof2.32m/s2,howlongwillittakefortheballDuringthefirstpartofthetrip,tohaveavelocityof1.23m/sdownthehill?12d�f�di�vitf�2atfLetthepositivedirectionbeupthehill.vd�12��12)(3.50s)2f�vi�atff�di�2atf��2(6.80m/s�41.6m600SolutionsManualPhysics:PrinciplesandProblems
602Chapter3continuedForthesecondpart,firstdetermine19.Arockisthrownupwardwithaspeedofthespeedofthecabattheendofthe26m/s.Howlongafteritisthrownwillthefirstaccelerationperiod.rockhaveavelocityof48m/stowardthevground?f�vi�atf�(0.00m/s)�(6.80m/s2)(3.50s)Takeupwardasthepositivedirection.v�23.8m/sf�vi�atfwherea��gvDuringthesecondaccelerationperiod,f�vi�48m/s�26m/st����2�v2�2a(df��g��9.80m/s2�7.6sv�dfifi)v2�v220.Thehigh-diveboardatmostpoolsisfid�d��fi�2a3.00mabovethewater.Adivinginstructor2divesofftheboardandstrikesthewater(0.00m/s)�(23.8m/s)����(2)(�9.60m/s2)1.18slater.�29.5ma.Whatwastheinitialvelocityofthediver?Thetotaldistancetraveledisthenthed�12wherea��gsumofthetwo.f�di�vitf�2atfdistance�41.6m�29.5m�71.1m1(d���(�g)t2f�di)��2f17.Acyclistridesataconstantspeedof12.0m/svi���tffor1.20minandthencoaststoastopwith(�3.00m)��1�2)(1.18s)2uniformacceleration21.2slater.Ifthetotal�2�(�9.80m/sdistancetraveledis1321m,thenwhatisthe����1.18saccelerationwhilethebikecoaststoastop?�3.24m/sDuringthefirstpartofthemotion,b.Howhighabovetheboarddidthetheridermovesatconstantspeed,diverrise?ora�0.00m/s2.Atthehighestpoint,thespeedisThedistancecoveredisthen0.00m/s.d�vt�(12.0m/s)(72s)�864m.v2�v2�2a(d�dThedistancecoveredduringthecoast-fifi)wherea��gingperiodisthen1321�864�457m.vf2�vi2d�d��2�v2�2a(dfi�2(�g)v�dfifi)(0.00m/s)2�(3.24m/s)2vf2�vi2(0.00m/s)2�(12.0m/s)2����(2)(�9.80m/s2)a�������2(d(2)(457m)f�di)�0.536m��0.158m/s218.Ahikertossesarockintoacanyon.Hehearsitstrikewater4.78slater.Howfardownisthesurfaceofthewater?Assumethatdownwardisthepositivedirection.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.12d�f�di�vitf�2atf�0.00m�(0.00m/s)(4.78s)����1(9.80m/s2)(4.78s)22�112mPhysics:PrinciplesandProblemsSolutionsManual601
6033.Drawafree-bodydiagramforasubmergedChapter4beachballasitrisestowardthesurfacejustpages862–864afterbeingreleased.Identifytheforcesacting1.Drawafree-bodydiagramforthespaceonthebeachballandindicatethedirectionshuttlejustafteritleavestheground.ofthenetforceandtheacceleration.Identifytheforcesactingontheshuttle.Makesurethatyoudonotneglectairresis-tance.Alsobesurethatyouindicatethedirectionoftheacceleration,aswellasthenetforce.FthrustFbuoyantFairresistanceFgThenetforceandaccelerationarebothFnetaupward.FgFwater2.Drawafree-bodydiagramforagoldfishresistancethatismotionlessinthemiddleofafish-Thenetforceandaccelerationvectorsbowl.Identifytheforcesactingontheareupward.fish.Indicatethedirectionofthenetforceonthefishandthedirectionoftheacceler-4.Muturiisrearrangingsomefurniture.Heationofthefish.pushesthedresserwithaforceof143N,andthereisopposingfrictionalforceofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.112N.Whatisthenetforce?Fnet�143N�112N�31N5.OneofthefloatsinaThanksgivingDayparaderequiresfourpeoplepullingonropestomaintainaconstantspeedof3.0km/hforthefloat.Twopeoplepullwithaforceof210Neach,andtheothertwopullwithaforceof140Neach.FbuoyantFgThenetforceandtheaccelerationarea.Drawafree-bodydiagram.bothzero.210N(�2)Ff140N(�2)602SolutionsManualPhysics:PrinciplesandProblems
604Chapter4continuedb.Whatistheforceoffrictionbetweenthec.Ifthebonehasamassof2.5kg,whatisfloatandtheground?itsacceleration?FFnet�210N�210N�140N�net�ma140N�FfFnet7N2a�����3m/s�0sincespeedisconstantm2.5kgF2Nf�7.0�108.Alargemodelrocketenginecanproduce6.Fivepeopleareplayingtug-of-war.Andersathrustof12.0Nuponignition.ThisandAlysonpulltotherightwith45Nandengineispartofarocketwithatotalmass35N,respectively.CalidandMarisolpulltoof0.288kgwhenlaunched.theleftwith53Nand38N,respectively.WithwhatforceandinwhatdirectiondoesBenitopullifthegameistied?Assignthecoordinatesystemsothatpositiveforcesaretotheright.Sincetheropeisnotaccelerating:Fnet�FAnders�FAlyson�FCalid�FMarisol�FBenitoa.Drawafree-bodyFthrust0N�45N�35N�53N�38N�diagramoftherocketFBenitojustafterlaunch.0N��11N�FBenitoFgb.WhatisthenetforcethatisactingonFBenito�11NthemodelrocketjustafteritleavestheBenitopullstotheright.ground?F7.Twodogsfightoverabone.Thelargerofnet�Fthrust�Fgthetwopullsonthebonetotherightwith�12.0N�(0.288kg)(�9.80m/s2)aforceof42N.Thesmalleronepullsto�9.2Nupwardtheleftwithaforceof35N.c.Whatistheinitialaccelerationoftherocket?Fnet�maFneta��m1.20N�(0.288kg)(�9.80m/s2)�����Dog1Dog20.288kga.Drawthefree-bodydiagramforthebone.�31.8m/s2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.35N42N9.Erikaisonanelevatorandpressesthebuttontogodown.Whentheelevatorb.Whatisthenetforceactingonthebone?firststartsmoving,ithasanaccelerationofF2downward.Erikaandtheelevatornet�42N�35N�7Ntotheright2.5m/shaveacombinedmassof1250kg.Physics:PrinciplesandProblemsSolutionsManual603
605Chapter4continueda.Drawafree-bodydiagramforthe12.Duringaspacelaunch,anastronauttypicallyelevator.undergoesanaccelerationof3gs,whichFmeansheexperiencesanaccelerationthatTisthreetimesthatofgravityalone.Whatwouldbetheapparentweightofa205-kgastronautthatexperiencesa3-gliftoff?FgLetupbethenegativedirection.b.WhatisthetensioninthecablethatFnet�Fg,apparent�Fg�maprovidestheupwardforceontheelevatorcar?Fg,apparent�Fg�maFnet�FT�Fg�ma�(205kg)(9.80m/s2)�F(205kg)(3)(�9.80m/s2)T�ma�Fg�8040N�(1250kg)(2.5m/s2)�(1250kg)(9.80m/s2)13.AlfonsoandSarahliketogoskydivingtogether.Alfonsohasamassof88kg,and�9100NupwardSarahhasamassof66kg.Whileinfreefall10.Nganhasaweightof314.5NonMarsandtogether,AlfonsopushesSarahhorizontallyaweightof833.0NonEarth.withaforceof12.3N.a.WhatisNgan’smassonMars?Fg,Earth�mgEarthFg,Earth833.0Na.WhatisAlfonso’shorizontalacceleration?m�������85.0kgg9.80m/s2EarthFonSarah�mSarahaSarahb.WhatistheaccelerationduetogravityFonSarahonMars,gMars?aSarah���mSarahFCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.g,Mars�mgMars12.3N2���0.19m/sF314.5N66kgg,Marsg���Mars�m�85.0kgb.WhatisSarah’shorizontalacceleration?�3.70m/s2FonAlphonso�FonSarah�mAlphonsoaAlphonso11.AlexisonthewrestlingteamandhasamassFof85.3kg.Beingawhizatphysics,hereal-onAlphonso12.3Na���izesthatheisoverthe830.0-NcutoffforhisAlphonso�m�88kgAlphonsoweightclass.Ifhecanconvincethetrainers2�0.14m/stomeasurehisweightintheelevator,whatmustbetheaccelerationoftheelevatorso14.A7.25-gbulletisfiredfromagun.Thethathejustmakeshisweightclass?muzzlevelocityofthebulletis223m/s.Fnet�Fg,apparent�Fg�maAssumethatthebulletacceleratesataconstantratealongthebarrelofthegunFg,apparent�Fga���beforeitemergeswithconstantspeed.mThebarrelofthegunis0.203mlong.830.0kg�(85.3kg)(�9.80m/s2)Whataverageforcedoesthebulletexert�����85.3kgonthegun?��0.0696m/s2byNewton’sthirdlawa�0.0696m/s2downFonbullet�Fongun604SolutionsManualPhysics:PrinciplesandProblems
606Chapter4continuedFonbullet�mbulletabulletv2�v2�2afibullet(df�di)27.5kg(223m/s)a��5m/s2bullet�(2)(0.203m)�1.22�102.5kgFonbullet�mbulletabullet�(0.00725kg)(1.22�105m/s2)�888Nso,888Nonthegun15.A15.2-kgpolicebatteringramexertsanaverageforceof125Nona10.0-kgdoor.a.Whatistheaverageaccelerationofthea.Whichlengthofstringwillbreakfirst?door?Afree-bodydiagramcanbedrawnByNewton’sthirdlaw,forthe2.5-kgmass,m1,andthetwomassestakentogether,mF1�m2.Letdoor�FramFT1bethetensioninthetopstring,Fdoor�mdooradoorandFT2thetensioninthemiddleFstring,andFT3thetensionapplieddoor125N2adoor��m��10.0�kg�12.5m/sbythephysicsteacher.doorb.WhatistheaverageaccelerationoftheFT1batteringram?Fram�mramaramFram125N2FT2a��ram�m�15.2kg�8.22m/sram16.Asademonstration,aphysicsteacherFgFT3attachesa7.5-kgobjecttotheceilingbyanearlymasslessstring.Thisobjectthensup-FT3Fgportsa2.5-kgobjectbelowitbyanother2.5kg�m110.0kg�m1�m2pieceofstring.Finally,anotherpieceofFstringhangsoffthebottomofthelowerT2�FT3�Fg�0objecttobepulledwitheverincreasingforceF2)�FT2�(2.5kg)(9.80m/sT3untilthestringbreakssomewhere.Thestring�24.5N�Fwillbreakwhenthetensionreaches156N.T3FT1�FT3�Fg�0F2)�FT1�(10.0kg)(9.80m/sT3�98.0N�FT3RegardlessoftheappliedforceCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.FT1�FT2�FT3.Therefore,theupperstringwillbreakfirst.b.Whatisthemaximumdownwardforcethephysicsteachercanapplybeforethestringbreaks?Physics:PrinciplesandProblemsSolutionsManual605
607Chapter4continuedThestringbreakswhenFb.Whatisthenormalforceonthesculp-T1�156N.FturewhenthetensioninthecableisT1�98.0N�FT319,250N?FT3�FT1�98.0N�156N�98.0NWhatisthenormalforceonthe�58Nsculpturewhenthetensioninthecableis19,250N?17.A10.0-kgobjectisheldupbyastringFnet�FT�FN�Fg�0thatwillbreakwhenthetensionexceeds1.00�102N.AtwhatupwardaccelerationFN��Fg�FTwillthestringbreak?�(2225kg)(�9.80m/s2)�Fnet�FT�Fg�ma19,250NF�2560NT�Fga��m2560Nupward1.00�102N�(10.0kg)(�9.80m/s2)������10.0kg�0.200m/s218.Alargesculptureisloweredintoplacebyacrane.Thesculpturehasamassof2225kg.Whenthesculpturemakescontactwiththeground,thecraneslowlyreleasestheten-sioninthecableasworkersmakefinaladjustmentstothesculpture’spositionontheground.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.a.Drawafree-bodydiagramofthesculp-turewhenitisincontactwiththeground,andthereisstilltensioninthecablewhiletheworkersmakethefinaladjustments.FTFNFg606SolutionsManualPhysics:PrinciplesandProblems
608Chapter5pages865–8671.Asoccerballiskickedfroma22-m-tallplatform.Itlands15mfromthebaseoftheplatform.Whatisthenetdisplacementoftheball?Sincethetwodistancesareperpendicular,usethePythagoreantheorem.R2�A2�B2R��A�2�B�2��(22m�)�2�(15m)�2�27m2.Ifthenetdisplacementis32mforthesamesituation,asdescribedinproblem1,howfarfromtheplatformbasemusttheballland?R2�A2�B2B��R�2�A�2���(32m)�2�(2�2m)2�23m3.Foranysingleforcevector,thereisonlyoneangleforwhichitsx-andy-componentsareequalinsize.a.Whatisthatangle?Rsin��Rcos�sin�R����cos�R��tan�1���R�tan�1(1)�45°Rb.Howmanytimesbiggerisavectoratthisparticularanglethaneitherofitscomponents?R11�������Rsin�sin�sin45°�1.4timesbigger4.Acueballonabilliardstabletravelsat1.0m/sfor2.0s.Afterstrikinganotherball,ittravelsat0.80m/sfor2.5satanangleof60.0°fromitsoriginalpath.a.Howfardoesthecueballtravelbeforeandafteritstrikes120.0°theotherball?Infirstlegitgoesxbefore�vbeforetbefore�(1.0m/s)(2.0s)�2.0mandinsecondlegCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.xafter�vaftertafter�(0.80m/s)(2.5s)�2.0mPhysics:PrinciplesandProblemsSolutionsManual607
609Chapter5continuedb.Whatisthenetdisplacementofthecueballfortheentire4.5-stimeinterval?Notethattheanglebetweenthetwolegsis120.0°,not60.0°.UsingthelawofcosinesR2�x2�y2�2xy(cos�)R��x�2�y�2�2xy�(cos��)��(2.0m�)�2�(2�.0m)2��(2)(2.0m�)(2.0m�)(cos�120.0�°)��3.5m5.Thetablebelowrepresentsasetofforcevectors.Thesevectorsbeginattheoriginofacoordinatesystem,andendatthecoordinatesgiveninthetable.�yVector#x-value(N)y-value(N)A0.06.0BB5.00.0C0.0�10.0Aa.Whatisthemagnitudeoftheresultantofthesumofthesethreevectors?CRx�Ax�Bx�Cx��x�0.0N�5.0N�0.0N�5.0NRRy�Ay�By�Cy�6.0N�0.0N�(�10.0N)��4.0NR��R�x2��Ry2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��(5.0N��)2�(�4.0N)�2��6.4Nb.Whatisthesizeoftheangle,�,thattheresultantmakeswiththehorizontal?R��tan�1���y��tan�1���4.0�N�R5.0Nx��39°c.Intowhichquadrantdoestheresultantpoint?Becausethex-componentispositiveandthey-componentisnegative,theresultantpointsintoquadrant4.6.A9.0-kgcratesitsonalevel,roughfloor.A61-Nforceisneededjusttostartitmoving.Whatisthesizeofthecoefficientofmaximumstaticfriction?ifthereisnomotion,Fapplied�Ff��sFN;therefore,FFappliedapplied������s�FmgN61N�����0.69(9.0kg)(9.80m/s2)608SolutionsManualPhysics:PrinciplesandProblems
610Chapter5continued7.Giventhegraphbelow,answerthefollowingIfvisconstant,Fapplied�Ff��kFNquestions.Fmappliedbucket�leadg4�k��F����FNN(0.255kg)(9.80m/s2)3����12N(N)�0.21fF2b.Ifsomeextrapelletsareadded,describe1thebehavioroftheblock.SinceFappliednowexceedsFf,0Fnet�0,theblockwillaccelerate2468overtime.FN(N)a.Whatisthevalueof�9.Aboattravels75kmsoutheast,then56kmkforthissystem?dueeast,then25km30.0°northofeast.�kistheslopeoftheline.a.SketchthevectorsetonaN-E-S-Wgrid.4N�0N���0.5N8N�0Nb.Ifthefrictionalforceis1.5N,whatisFN?WEFromthegraph,FN�3Nc.DoestriplingFNtripleFapplied?SYes,theyaredirectlyproportional.b.FinditsnetE-Wcomponentofdisplace-d.DoFappliedandFNactinthesamementandnetN-Scomponentofdirection?Explainwhyorwhynot.displacement.No,thefrictionforceactshorizontallyREW�AEW�BEW�CEWandoppositetoappliedforce,whilethenormalforceactsperpendicular�(75km)(cos(�45°))�tothefixedsurface.(56km)(cos0.0°)�(25km)(cos30.0°)8.Awoodenblocksitsonalevellabtable.Astringdrapedoverapulleyconnectstoa�1.3�102kmbucketthatcanbefilledwithleadpellets.RNS�ANS�BNS�CNSMaggiewantstomeasurehowmuchappliedmass(pellets�bucket)isneededtomove�(75km)(sin(�45°))�theblockalongthetableataconstantspeed.(56km)(sin0.0°)�(25km)(sin30.0°)��41kmc.Finditsnetdisplacement.R��R�EW2��RNS2�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��(1.3��10�2km)�2�(�41km�)�2a.Iftheappliedmassofthebucketand�136kmtheleadpelletsis0.255kg,andtheblockhasaweightof12N,whatisthevalueof�k?Physics:PrinciplesandProblemsSolutionsManual609
611Chapter5continuedd.FinditsnetanglerelativetoanE-Waxis.Ff�Fnet�ma(NonegativesignRherebecausethevalueofashould��tan�1���NSRincorporatethat.)EW�1��41�kmThus,�tan�2�1.3�10km��kFN�ma��18°��kmg�ma�18°southofeast�a��k�g10.A1.25-kgboxisbeingpulledacrossalevelsurfacewhere�v2�v2kis0.80.Ifthestringissud-v2�v2�2ad,soa��f�idenlycut,causingtheappliedforcetofi2dimmediatelygoto0.0N,whatistherateofv2�v2fiaccelerationoftheblock?���2d���k��gLetthedirectionoftheappliedforcebepositive.�(v2�v2)fi���Thenetforceontheboxisdueto2dgfrictionandisinthenegativedirection.�((0.0m/s)2�(21m/s)2)�����0.36Fnet�ma�Ff��kFN��kmg(2)(62m)(9.80m/s2)a��2)b.Willtheanswerchangeifapuckofkg�(0.80)(9.80m/sdifferentmass,butsamematerialand�7.8m/s2inthenegativedirectionshapeisused?Explainwhyorwhynot.11.Ifthevelocityoftheboxinproblem10wasNo,theresultisindependentof5.0m/sattimezero,whatwillbeitsspeedmass.Notehowitcancelsinaboveafter0.50s?Howfarwillittravelinthatsolution.timeinterval?13.A105-Nsuitcasesitsonarubberrampatvf�vi�atanairportcarouselata25°angle.TheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.v2)(0.50s)f�5.0m/s�(�7.8m/sweightvectorcanbebrokenintotwo�1.1m/sperpendicularcomponents.v2�v22�(5.0m/s)2fi(1.1m/s)105Nd�������2a(2)(�7.8m/s2)�1.5mFx�Fy12.A0.17-kghockeypuckleavesthestickonaslapshottraveling21m/s.Ifnootherforces�actonthepuck,frictioneventuallywillFgbringittorest62maway.a.Whatisthemagnitudeofthecompo-a.Basedonthesedata,determinethenentparalleltotherampsurface?valueof�kforthishockeypuckonice.FLetthedirectionofmotionbeposi-x�Fwsin��(105N)(sin25°)tive.Thus,theforceoffrictionisin�44Nthenegativedirection.b.Whatisthemagnitudeofthecompo-Fnentatarightangletotherampf���kFN(Remember:frictionisinthenegativedirection.)surface?Fy�Fwcos��(105N)(cos25°)�95N610SolutionsManualPhysics:PrinciplesandProblems
612Chapter5continuedc.Whichofthosecomponentsisthemgsin��magsin��anormalforce?�k��mgc�os����gcos�Fyvfgsin����t���14.Inproblem13,whichforceoffsetsthegcos�kineticfrictionforce?IfFxexceedsFf,will(9.80m/s2)(sin42°)���15m�/s�thesuitcaseacceleratedowntheramp?3.0s����(9.80m/s2)(cos42°)Thecomponentparalleltoramp,Fx,offsetsthefrictionforce.SinceFnet�0.21alongrampnolongerequalszero,thesuitcasewillaccelerate.17.A64-Nboxispulledbyaropeataconstantspeedacrossaroughhorizontalsurface.15.DaliladecidestodeterminethecoefficientIfthecoefficientofkineticfrictionis0.81,ofmaximumstaticfrictionforwoodagainstwhatisthemagnitudeoftheappliedforcewoodbyconductinganexperiment.Firstifthatforceisdirectedparalleltothefloor?sheplacesablockofwoodonasmallFapplied�FfsinceFnet�0plank;next,sheslowlyliftsoneendoftheplankupward.ShenotestheangleatwhichFf��kFN�(0.81)(64N)�52Ntheblockjustbeginstoslide,andclaimsthat�18.Supposethatinproblem17theapplieds�tan�.Sheiscorrect.Showwhy.forceisdirectedbytheropeatanangle,�,tothefloor.a.ThenormalforceisnolongersimplyFg.Showhowtocomputenetverticalforce.�Fnet,y�Fg�(�Fappliedsin�)b.Thefrictionalforcestillopposesthehorizontalmotionofthebox.Showhowtocomputenethorizontalforce.Ifthereisnomotion,FnetalongtheFnet,x�Fappliedcos��(�Ff)ramp�0and�FFappliedcos���kFNx�Fwsin��Ff��sFN��sFwcos�Fwsin��Fappliedcos���kFnet,yThus,����tan�s�Fcos�wThisworks,regardlessoftheweightoftheblock.16.Jonathan,withamassof81kg,startsatrestfromthetopofawaterslideangledat42°fromtheground.Heexitsatthebottom3.0slatergoing15m/s.Whatis�k?vf�vi�atwherevi�0Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.vfa���tFnet�ma�Fg�Ff�Fg��kFn�mgsin���kmgcos�Physics:PrinciplesandProblemsSolutionsManual611
613Chapter6�yElectronbeamdpages867–8681.Afootballplayerkicksafieldgoalfromadis-�xtanceof45mfromthegoalpost.Thefootball�dislaunchedata35°angleabovethehorizon-Deflectorplatestal.WhatinitialvelocityisrequiredsothatthefootballjustclearsthegoalpostcrossbarthatLocatetheoriginofthecoordinatesys-is3.1mabovetheground?Ignoreairresis-temmidwaybetweentheplatesatthetanceandthedimensionsofthefootball.leftedge.Therebyyi�0andvyi�0.TheoriginofthecoordinatesystemisThepositionofanelectronintheregionatthepointofthekick.oftheplatesisgivenby:vat2xi�vicos�x�v�xit,y�2vyi�visin�Eliminatingtgivesthetrajectory:Lettbethetimewhenthefootballax2a2crossestheverticalplaneofthey��2������2xvxi2vxiuprights.Then:Werequirethetrajectorytopassthroughx�vxitthepointjustbeyondthedeflectionplate:xsot���a2vxiy��2v2xxigt2y�v�Then,yit�26m/s)20.010mx22v2y(2)(3.0�10��2��g����a��xi�����xvxix2(0.100m)2�vyi��v����2xi�9.0�1012m/s2xgx2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(v����isin�)��vicos�����2(v2�3.Askateboardtrackhasahorizontalsegmenticos�)2followedbyarampthatdeclinesata45°gx�(tan�)(x)�2��v2(cos�)2angle,asshown.igx2v���i����2(cos�)2((tan�)(x)�y)(9.80m/s2)(45m)2����������(2)(cos35°)2((tan35°)(45m)�3.1m)�23m/s45°2.Inacertaincathode-raytube,abeamofelectrons,movingataconstantvelocity,entersaregionofconstantelectricforcea.Howlongwouldtherampneedtobetomidwaybetweentwoparallelplatesthatareprovidealandingforaskateboarderwho10.0cmlongand1.0cmapart.Inthislaunchesfromthehorizontalsegmentatregion,theelectronsexperienceanaccelera-avelocityof5.0m/s?tion,a,towardtheupperplate.Iftheelec-Theskateboarder’strajectoryistronsenterthisregionatavelocityofgivenby:3.0�106m/s,whatistheaccelerationthatg2,for0�x�xy���xneedstobeappliedsothattheelectrons2v2Lxijustmisstheupperdeflectionplate?612SolutionsManualPhysics:PrinciplesandProblems
614Chapter6continuedTherampcanberepresentedbytheIfthecoordinatesystemischosenequation:sothattheoriginisontheflooraty��xthepointtheballisthrown,thentheheightoftheballovertimeis:Byeliminatingy,wecanfindtheval-gt2uesofxthatsatisfybothequations.y�y�i�vyit�2gx2�x�gx�1x�0�2��2�Attimet,themaximumheightis2v2vxixi2vyigvyi2x�0,x�2v�xi�xymax�yi�vyi���g������2�g�gLThesecondsolutionrepresentsthev2gv2yiyi�y��pointwheretheskateboarderreturnsi�g�2g2totheramp.v2v2(sin�)2yii(2)(5.0m/s)2�yi���yi���x��2g2gL�9.80m/s2�5.1m(10.0m/s)2(sin68°)2yL��xL��5.1m�1.50m����2)(2)(9.80m/sx�5.9mL�Lrampcos�xL�5.1mb.Ifthebasketrimheightis3.05m,howL��ramp�cos��cos45°��7.2mfarabovetherimistheball?ThenegativesignisbecauseoftheThehorizontalpositionoftheballcoordinatesystemassigned.Theovertimeis:lengthoftherampisapositivex�vxit�(vicos�)(t)value:7.2m.xsot��b.Iftheinitialvelocityisdoubled,whatvicos�happenstotherequiredlengthoftheTheheightoftheballthenis:ramp?gt2Notethattherequiredramplengthisyrim�yi�vyit��2proportionaltothesquareoftheini-xtialvelocity.Therefore,therequired�yi�visin����v�icos�ramplengthisquadrupledto28.8m.gx2������2v4.Inanattempttomakea3-pointshotfromicos�adistanceof6.00m,abasketballplayergx2�y��loftstheballatanangleof68°abovethei�tan�x�v2(cos�)2ihorizontal.Theballhasaninitialvelocityof10.0m/sandaninitialdistancefromthe�1.50m�(tan68°)(6.00m)�floorof1.50m.(9.80m/s2)(6.00m)2���a.Whatisthemaximumheightreached(2)(10.0m/s)2(cos68°)2bytheball?�3.78mTheverticalcomponentoftheveloc-heightaboverim�3.78m�3.05m�ityovertimeis:0.73mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.vy�vyi�gtTheballis0.73mabovetherim.Themaximumheightoccursattimet5.Howfardoesabaseballthatisthrownhori-1whentheverticalvelocityiszero.zontallyat42.5m/sdropoverahorizontalvyit���distanceof18.4m?gPhysics:PrinciplesandProblemsSolutionsManual613
615Chapter6continuedThetimeneededbythebaseballtotravel(2)(vR����icos�)(visin�)18.4misgx�v�x(v2)(2)(sin�)(cos�)xt,sot�v����ixgInthistimeintervaltheballdropsandusethetrigonometricidentitygt2gx2�y���������2sin�cos��sin2�toget22vx2vR��isin2�9.80m/s218.4m2g��������242.5m/sb.Whatlaunchangle,�,resultsinthe�0.918mlargestrange?sinehasamaximumvalueat90°so,6.Aprojectileislaunchedfromzeroheight2��90°withaninitialangle,�,abovethehorizon-talandwithaninitialvelocity,v��45°i.a.Showthattherangeoftheprojectile—Rismaximumwhen��45°thedistancefromthelaunchpointat7.Ifaringwereconstructedaspartofaspacewhichtheheightisagainzero—isstation,howfastmusta50.0-m-radiusringgivenby:rotatetosimulateEarth’sgravity?v2R�i�sin2��Forobjectsinuniformcircularmotion,gv2thecentripetalaccelerationisa�Locatetheoriginofthecoordinatec�r.systematthepointoflaunch.TheTosimulateEarth’sgravity,settheprojectilecoordinatesovertimearecentripetalaccelerationtog.givenby:v2a�c�r�g12x�vxit,y�vyit��2gtv2�grCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Eliminatingtgivesthetrajectoryv��gr�path.vyig2��(9.80�m/s�2)(50.0�m)��22.1m/sy��x��xvxi2v2xiTherequiredperiodTisvyig(2�)(50.0m)�x����x�T��2�r����14.2svxi2v2v22.1m/sxiSettingy�0givesthetworootsof8.Aturntableforvinylrecordsworksbycon-thisequation.strainingtheneedletotrackinsideagroovevyiginaverycloseapproximationofuniformx�0,���x�0vxi2v2xicircularmotion.IftheturntablerotationalThesecondisthesolutionofinterest.1speedis33��rpm,whatistheneedle’s3SolveforxandrenameitasR.centripetalaccelerationwhenitis14.6cm2vxivyifromthecenter?R��g1Substitute:(33�rev/min)�0.55rev/s3vxi�vicos�,vyi�visin�,T���1�1.80s0.556rev/s4�2r4�2(0.146m)2a���c�T2�1.80s�3.20m/s614SolutionsManualPhysics:PrinciplesandProblems
616Chapter6continued9.AparkrideisdesignedsothattheriderisThedirectionis:ontheedgeofarevolvingplatform,3.5mvRP3.7m/sfromtheplatform’scenter.Thisplatformis��tan�1����tan�1���v4.2m/sPQmounted8.0mfromthecenterofalarger�41°northofeastrevolvingplatform.Thesmallerplatformmakesonerevolutionin6.0sandcom-10.Twoobjectsareplacedonaflatturntablepletes2.0revforeachrevolutionoftheat10.0cmand20.0cmfromthecenter,largerplatform.Allrotationsarecounter-respectively.Thecoefficientofstaticfrictionclockwise.Attheinstantshown,whatarewiththeturntableis0.50.Theturntable’sthemagnitudeandthedirectionoftherotationalspeedisgraduallyincreased.rider’svelocitywithrespecttotheground?a.Whichofthetwoobjectswillbegintoslidefirst?Why?Theouterobjectslidesfirst.The4�2rcentripetalaccelerationa�c�T2isQproportionaltotheradius,r.Thecentripetalaccelerationisprovidedbythefrictionalforceuptothelimit8.0mvRPspecifiedbythecoefficientofstaticPfriction.Therefore,atanygivenrota-vPQRtionalspeed,thefrictionalforceisgreaterfortheobjectatthelarger3.5mradius,andtheforceonthatobjectreachesthelimitfirst.LetthevelocityoftheriderRwithrespecttopointPbevb.AtwhatrotationalspeeddoestheinnerRP.TheperiodofplatformPis6.0s,sothemagnitudeobjectbegintoslide?anddirectionofvRPisLetvbethevelocityinm/s.Then,2�rv22�r(2�)(3.5m)v��,anda�vRP�����Tc�r.T6.0sAtthemaximumangularvelocity,�3.7m/s,norththefrictionalforceFf��sFN��TheperiodofplatformQis(2.0)(6.0s)�smgmustbeequaltomac.12s,sothemagnitudeanddirectionmv2��ofvsmg�rPQisv�2�r��(2�)(8.0m)v����sgrPQ�T�12s�4.2m/s,east��(0.50)�(9.80�m/s�2)(0.10�m)�Thevelocityoftheriderwithrespectto�0.70m/sthegroundis11.Anairplane’sairspeedis2.0�102km/hvRQ�vRP�vPQdueeast.BecauseofawindblowingtovRQ���vRP2��vPQ2thenorth,itisapproachingitsdestination15°northofeast.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�vRQ���(3.7m�/s)�2��(4.2m�/s)2a.Whatisthewindspeed?�5.6m/svwindtan���vairPhysics:PrinciplesandProblemsSolutionsManual615
617Chapter6continuedvwind�vairtan�Chapter7�(2.0�102km/h)(tan15°)pages868–869�54km/h1.Ayearisdefinedasthetimeittakesforab.Howfastistheairplaneapproachingitsplanettotravelonefullrevolutionarounddestination?theSun.OneEarthyearis365days.UsingthedatainTable7-1,calculatethenumbervcos���airofEarthdaysinoneNeptuneyear.IfvgroundNeptunetakesabout16htocompleteonevv�airofitsdays,howmanyNeptuniandayslongground�cos�isNeptune’syear?2.0�102km/h23���TNrNcos15°�������TrEE�2.1�102km/hT2r3T�E�NN���r3�12.Ariverisflowing4.0m/stotheeast.AEboateronthesouthshoreplanstoreacha(365days)2(4.50�1012m)3dockonthenorthshore30.0°downriverby��������(1.50�1011m)3headingdirectlyacrosstheriver.�6.00�104EarthdaysForevery16Earthdays,therewillbe24Neptuniandays,4Earthdays)24Neptuniandays(6.00�10�����16Earthdays30.0°4Neptuniandays�9.00�102.SupposeanewplanetwasdiscoveredtoorbittheSunwithaperiod5timesthatCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ofPluto.UsingthedatainTable7-1,calcu-latetheaveragedistancefromtheSuna.Whatshouldbetheboat’sspeedrelativeforthisnewplanet.tothewater?T2r3���A����ALetvb/wbetheboat’sspeedrelativeTPrPtothewater.Then,LetTP�periodforPlutovtan���wvb/wTA�periodfornewplanet�5TPvw4.0m/s3T2r3v���r�A�Pb/w�tan��tan30.0°A���T2�P�6.9m/s3(5T2(5.87�1012m)3b.Whatistheboat’sspeedrelativetothe����P)���T2dock?P2�2�1.72�1013mvb/d���vw�vb/w��(4.0m�/s)�2��(6.9m/s)�23.IfameteoritehittheEarthandmovedit2.41�1010mclosertoVenus,howmany�8.0m/sdayswouldtherebeinanEarthyear?UsethedatainTable7-1.616SolutionsManualPhysics:PrinciplesandProblems
618Chapter7continuedNewaveragedistancefromtheSun�T2r3���A����ATrBBT2r3T�B�AA���r3�B(365days)2(1.50�1011m�2.41�1010m)3�����������(1.50�1011m)3�281days4.TheMoonisasatelliteoftheEarth.TheMoontravelsonefullrevolutionaroundtheEarthin27.3days.GiventhatthemassoftheEarthis5.97�1024kg,whatistheaveragedistancefromtheEarthtotheMoon?Lookatunitsfirst:Theperiodisgiventousindays,whichmustbeconvertedtosecondsduetotheunitsofG.24h60min60s6s(27.3days)����������2.36�101day1h1minr3T�2����GMET2GM3Er����24�3(2.36�106s)2(6.67�10�11N�m2/kg2)(5.97�1024kg)�������������4�2�3.83�108m5.Asatellitetravels7.18�107mfromthecenterofoneoftheplanetsinoursolarsystemataspeedof4.20�104m/s.UsingthedatainTable7-1,identifytheplanet.GMv����rv2r(4.20�104m/s)2(7.18�107m)27kg,JupiterM��������1.90�10G6.67�10�11N�m2/kg26.Earth’satmosphereisdividedintofourlayers:thetroposphere(0–10km),thestratosphere(10–50km),themesosphere(50–80km),andthethermosphere(80–500km).Whatistheminimumvelocityanobjectmusthavetoenterthethermosphere?r�h�r4m�6.38�106mE�8.0�10GMv����Er(6.67�10�11N�m2/kg2)(5.97�1024kg)������Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.����8.0�104m�6.38�106m�7.8�103m/sPhysics:PrinciplesandProblemsSolutionsManual617
6196.A92-kgmanusesa3.05-mboardtoattemptChapter8tomoveaboulder,asshowninthediagrampages869–870below.Hepullstheendoftheboardwitha1.Therotationalvelocityofamerry-go-forceequaltohisweightandisabletomoveroundisincreasedataconstantratefromitto45°fromtheperpendicular.Calculate1.5rad/sto3.5rad/sinatimeof9.5s.thetorqueapplied.Whatistherotationalaccelerationofthemerry-go-round?��(3.5rad/s)�(1.5rad/s)��������t9.5s�0.21rad/s245°2.Arecordplayer’sneedleis6.5cmfromthecenterofa45-rpmrecord.Whatisthevelocityoftheneedle?Firstconvertrpmtorad/s.45rev2�rad1min��Frsin�����������4.71rad/s1min1rev60s�mgrsin�1mv�r��(6.5cm)���(4.71rad/s)�(92kg)(9.80m/s2)(3.05m)(sin45°)100cm�0.31m/s�1.9�103N�m3.Supposeabaseballrolls3.2macrossthe7.Ifa25-kgchildtriestoapplythesametorquefloor.Iftheball’sangulardisplacementisasinthepreviousquestionusingonlyhisor82rad,whatisthecircumferenceoftheball?herweightfortheappliedforce,whatwouldthelengthoftheleverarmneedtobe?d�r�d3.2mL�rsin�r�����82rad�0.039m��1.9�103N�mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��������Fmg(25kg)(9.80m/s2)c�2�r�2�(0.039m)�0.25m�7.8m4.Apainterusesa25.8-cmlongscrewdrivertoprythelidoffofacanofpaint.Ifaforceof8.Logan,whosemassis18kg,sits1.20m85Nisappliedtomovethescrewdriver60.0°fromthecenterofaseesaw.IfShiromustfromtheperpendicular,calculatethetorque.sit0.80mfromthecentertobalance��Frsin��(85N)(0.258m)(sin60.0°)Logan,whatisShiro’smass?�19N�mFLrL�FSrSmLgrL�mSgrS5.Aforceof25Nisappliedverticallyatthemendofawrenchhandlethatis45cmlongm�LrLS�rtotightenaboltintheclockwisedirection.SWhattorqueisneededbythebolttokeep(18kg)(1.20m)���thewrenchfromturning?0.80mInordertokeepthewrenchfromturn-�27kging,thetorqueontheboltmustbeequal9.Twoforces—55-Nclockwiseand35-Ninmagnitudebutoppositeindirectionofcounterclockwise—areappliedtoamerry-thetorqueappliedbythewrench.go-roundwithadiameterof4.5m.Whatis��Frsin��(25N)(0.45m)(sin90.0°)thenettorque?�11N�mcounterclockwise618SolutionsManualPhysics:PrinciplesandProblems
620Chapter8continued12.Amerry-go-roundintheparkhasaradiusof2.6mandamomentofinertiaof1773kg�m2.Whatisthemassofthemerry-go-round?4.512mI��mr22I(2)(1773kg�m2)35Nm�����r2(2.6m)255N�5.2�102kg13.Themerry-go-rounddescribedintheprevi-Thenettorqueisthesumoftheousproblemispushedwithaconstantforceindividualtorques.of53N.Whatistheangularacceleration?�����netnet��ccw��cwI�Fccwrsin��Fcwrsin�Frsin���1�(Fccw�Fcw)rsin�(53N)(2.6m)(sin90.0°)�����(35N�55N)��4.5m�(sin90.0°)1773kg�m22�7.8�10�2rad/s2��45N�m45N�mclockwise14.Whatistheangularvelocityofthemerry-go-rounddescribedinproblems12and1310.Astudentsitsonastoolholdinga5.0-kgafter85s,ifitstartedfromrest?dumbbellineachhand.Heextendshisarms���f��isuchthateachdumbbellis0.60mfromthe������t�taxisofrotation.Thestudent’smomentof�inertiais5.0kg�m2.Whatisthemomentofi�0sinceitstartedfromrestinertiaofthestudentandthedumbbells?�f���tI2�(5.0kg)(0.60m)2�(7.8�10�2rad/s2)(85s)singledumbbell�mr�1.8kg�m2�6.6rad/sItotal�2Isingledumbbell�Istudent15.Anice-skaterwithamomentofinertiaof�(2)(1.8kg�m2)�5.0kg�m21.1kg�m2beginstospinwithherarmsextended.After25s,shehasanangular�8.6kg�m2velocityof15rev/s.Whatisthenettorqueactingontheskater?11.Abasketballplayerspinsabasketballwitharadiusof15cmonhisfinger.Themassof�net�I�theballis0.75kg.WhatisthemomentofI(���f��i)inertiaaboutthebasketball?��tI��2mr2����22(1.1kg�m2)(15rev/s�0rev/s)55(0.75kg)(0.15m)�������255Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�6.8�10�3kg�m22�rad���rev�4.1N�mPhysics:PrinciplesandProblemsSolutionsManual619
621Chapter8continued16.Aboardthatis1.5mlongissupportedintwoplaces.Iftheforceexertedbythefirstsupportis25Nandtheforcedexertedbythesecondis62N,whatisthemassoftheboard?Fnet�F1�F2�(�Fg)Sincethesystemisinequilibrium,Fnet�0.0�F1�F2�FgFg�F1�F2mg�F1�F2F1�F225N�62Nm������g9.80m/s2�8.9kg17.Achildbeginstobuildahouseofcardsbylayingan8.5-cm-longplayingcardwithamassof0.75gacrosstwootherplayingcards:supportcardAandsupportcardB.IfsupportcardAis2.0cmfromtheendandexertsaforceof1.5�10�3N,howfarfromtheendissupportcardBlocated?LettheaxisofrotationbeatthepointsupportcardAcomesincontactwiththetopcard.Fnet�FA�FB�(�Fg)Sincethesystemisinequilibrium,Fnet�0.0�FA�FB�FgFB�Fg�FACopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�mg�FASincetheaxisofrotationisaboutsupportcardA,�A�0.so�net��B��gThesystemisinequilibrium,so�net�0.0��B��g�B���g�B�rBFBand�g��rgFgrBFB�rgFgrrgFggmgr���B�F�mg�FBA���1��(0.085m)�0.020m�(7.5�10�4kg)(9.80m/s2)2��(7.5��10�4�kg)(9.80m/s�2)��1.5��10�3N�2.8�10�2m�28cm620SolutionsManualPhysics:PrinciplesandProblems
622Chapter8continued18.IfsupportcardAinthepreviousproblemwasmovedsothatitnowis2.5cmfromtheend,howfarfromtheotherenddoessupportcardBneedtobetoreestablishequilibrium?rgmgr��B�mg�FA���1��(0.085m)�0.025m�(7.5�10�4kg)(9.80m/s2)2��(7.5��10�4�kg)(9.80m/s�2)��1.5��10�3N�2.2�10�2m�22cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual621
623Chapter9pages870–8711.Aballwithaninitialmomentumof6.00kg�m/sbouncesoffawallandtravelsintheoppositedirectionwithamomentumof4.00kg�m/s.Whatisthemagnitudeoftheimpulseactingontheball?Choosethedirectionawayfromthewalltobepositive.pf��4.00kg�m/spi��6.00kg�m/sImpulse�pf�pi�(4.00kg�m/s)�(�6.00kg�m/s)�10.0kg�m/s2.Iftheballinthepreviousprobleminteractswiththewallforatimeintervalof0.22s,whatistheaverageforceexertedonthewall?Impulse�F�tImpulse10.0kg�m/sF�������45N�t0.22s3.A42.0-kgskateboardertravelingat1.50m/shitsawallandbouncesoffofit.Ifthemagnitudeoftheimpulseis150.0kg·m/s,calculatethefinalvelocityoftheskateboarder.Choosethedirectionawayfromthewalltobepositive.Impulse�pf�pi�mvf�(�mvi)�m(vf�vi)Impulsev��Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.f�m�vi150.0kg�m/s����1.50m/s42.0kg�2.07m/s4.A50.0-gtoycartravelingwithavelocityof3.00m/sduenorthcollideshead-onwithan180.0-gfiretrucktravelingwithavelocityof0.50m/sduesouth.Thetoyssticktogetherafterthecollision.Whatarethemagnitudeanddirectionoftheirvelocityafterthecollision?Choosenorthtobepositive.pi�pfpci�pti�pfmcvci�mtvti�(mc�mt)vfmv��cvci�mtvtif�mc�mt(50.0g)(3.00m/s)�(180.0g)(�0.50m/s)������50.0g�180.0g�0.26m/s,duenorth622SolutionsManualPhysics:PrinciplesandProblems
624Chapter9continued5.A0.040-kgbulletisfiredintoa3.50-kgThesecondskatermoveswestwithablockofwood,whichwasinitiallyatrest.velocityof1.3m/s.Thebulletremainsembeddedwithintheblockofwoodafterthecollision.The8.Supposea55.0-kgice-skater,whowasbulletandtheblockofwoodmoveatainitiallyatrest,firesa2.50-kggun.Thevelocityof7.40m/s.Whatwastheoriginal0.045-kgbulletleavesthegunatavelocityvelocityofthebullet?of565.0m/s.Whatisthevelocityoftheice-skateraftershefiresthegun?pi�pfppi�pfbi�pwi�pf0�pmfs�pfbbvbi�mwvwi�(mb�mw)vf�(mwherevs�mg)vfs�mbvfbwi�0.Thus,becausethefinalmassoftheskater(0.040kg�3.50kg)(7.40m/s)includesthemassofthegunheldbyv����bi�0.040kgtheskater.Then,�6.5�102m/s�mv��bvfbfs�ms�mg6.BallA,withamassof0.20kg,strikesballB,�(0.045kg)(565.0m/s)withamassof0.30kg.Theinitialvelocity����55.0kg�2.50kgofballAis0.95m/s.BallBisinitiallyatrest.Whatarethefinalspeedanddirection��0.44m/sofballAandBafterthecollisionifthey9.A1200-kgcannonisplacedatrestonsticktogether?anicerink.A95.0-kgcannonballisshotpi�pffromthecannon.IfthecannonrecoilsatmAvAi�(mA�mB)vfaspeedof6.80m/s,whatisthespeedofmthecannonball?v��AvAif�mpA�mBi�pf(0.20kg)(0.95m/s)Sincethecannonandcannonballareat����0.20kg�0.30kgrestbeforetheblast,pi�0.00kg�m/s.�0.38m/sinthesamedirectionasSopballA’sinitialvelocityfc��pfbmcvfc��mbvfb7.Anice-skaterwithamassof75.0kgpushes�mv�cvfcoffagainstasecondskaterwithamassoffb�mb42.0kg.Bothskatersareinitiallyatrest.�(1200kg)(6.80m/s)Afterthepush,thelargerskatermovesoff����95.0kgwithaspeedof0.75m/seastward.Whatisthevelocity(magnitudeanddirection)of��86m/sthesmallerskaterafterthepush?10.An82-kgreceiver,moving0.75m/snorth,pi�pfistackledbya110.0-kgdefensivelineman�m1vf1�m2vf2moving0.15m/seast.Thefootballplayershitthegroundtogether.Calculatetheirfinal�mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.v�1vf1f2�mvelocity(magnitudeanddirection).2p�(75.0kg)(0.75m/s)ri�mrvri,y�(82kg)(0.75m/s)����42.0kg�62kg�m/snorth��1.3m/spdi�mdvdi,x�(110.0kg)(0.15m/s)�16kg�m/s,eastPhysics:PrinciplesandProblemsSolutionsManual623
625Chapter9continuedLawofconservationofmomentumstatespi�pfpf,x�pi,x�16kg�m/spf,y�pi,y�62kg�m/s1p2�p2)�2�f�(pf,xf,y1�((16kg�m/s)2�(62kg�m/s)2)�2��64kg�m/spf64kg�m/sv�����f�m�82kg�110.0kgr�md�0.33m/sp�1f,y��tan���pf,xm�1rvri,y�tan���mdvdi,x�1(82kg)(0.75m/s)�tan�����(110.0kg)(0.15m/s)�75°11.A985-kgcartravelingsouthat29.0m/shitsatrucktraveling18.0m/swest,asshowninthefigurebelow.Afterthecollision,thevehiclessticktogetherandtravelwithafinal29.0m/smomentumof4.0�104kg�m/satCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.anangleof45°.Whatisthemass18.0m/softhetruck?45°p2�p2�p2ffxfyp2�p2�p2fixiyp2�m2v2�m2v2fccitti12�m2v2�2�4pp�4.0�10kg�m/sm��fccit���v2ti14kg�m/s)�(985kg)2(29.0m/s)2��(4.0�102��������(18.0m/s)2�1.6�103kg624SolutionsManualPhysics:PrinciplesandProblems
626Chapter9continued12.A77.0-kgwomaniswalking0.10m/seastinthegym.Amanthrowsa15.0-kgballsouthandaccidentallyhitsthewoman.Thewomanandtheballmovetogetherwithavelocityof0.085m/s.Calculatethedirectionthewomanandtheballmove.p��cos�1���fxpfp�cos�1���ixpfm�cos�1����wviw(mw�mb)vf(77.0kg)(0.10m/s)�cos�1������(77.0kg�15.0kg)(0.085m/s)�1.0�101degreessouthofeastCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual625
6275.Ifthetwo-blocksystemdescribedintheChapter10previousproblemwasinitiallyatrest,whatpage871isthefinalvelocity?1.Atoytruckispushedacrossatable0.80m12�KE��m�vnorth,andpulledbackacrossthetable20.80msouth.Ifaconstanthorizontalforce12��m(vof15Nwasappliedinbothdirections,2f�vi)whatisthenetwork?vi�0sinceblockswereinitiallyatrest.Choosenorthtobethepositivedirection.12So�KE��mv2fWnet�Wnorth�Wsouth2�KE(2)(77J)�(Fd)�(�Fd)vf����m����15kg�(15N)(0.80m)�(�15N)(0.80m)�3.2m/s�0.0J6.Atoycarwithamassof0.75kgispulled2.A15-kgchildexperiencesanaccelerationof3.2macrossthefloorwithaconstantforce0.25m/s2assheispulled1.7mhorizontallyof110N.If67Jofworkisdone,whatistheacrossthefloorbyhersister.Calculatetheupwardangleoftheforce?changeinthechild’skineticenergy.W�Fdcos��KE�W�Fd�mad�1W��cos����(15kg)(0.25m/s2)(1.7m)Fd�6.4J�167J�cos�����79°(110N)(3.2m)3.Amanpushesacouchadistanceof0.75m.7.Ifa75-Wlightbulbisleftonfor2.0h,howIf113Jofworkisdone,whatisthemagni-muchworkisdone?tudeofthehorizontalforceapplied?W�Fd3600s3s(2.0h)����7.2�101.0hCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.W113J2NF�����1.5�10Wd0.75mP��t4.TwoblocksaretiedtogetherbyahorizontalW�Pt�(75W)(7.2�103s)stringandpulledadistanceof2.7macross�5.4�105Janairhockeytablewithaconstantforceof35N.Theforceisdirectedatanupward8.A6.50-horsepower(hp)self-propelledangleof35°fromthe9.0-kgblock,aslawnmowerisabletogofrom0.00m/sshowninthefigure.Whatisthechangeinto0.56m/sin0.050s.Ifthemassofthekineticenergyinthetwo-blocksystem?lawnmoweris48.0kg,whatdistancedoesthelawnmowertravelinthistime?35N(Use1hp�746W.)35°746W3W6.0kg9.0kg(6.50hp)���1hp�4.85�10�va��tW��KE�Fdcos��(35N)(2.7m)(cos35°)�77J626SolutionsManualPhysics:PrinciplesandProblems
628Chapter10continuedW11.Aworkerusesapulleytolifta45-kgobject.P��tIfthemechanicaladvantageofthepulleyisFdmad5.2,whatistheeffortforceexertedbythe����ttworker?�vFrm��t��dm(vMA��f�vi)dF����ett2Frmg(45kg)(9.80m/s2)Pt2Fe��������d���MAMA5.2m(vf�vi)�85N(4.85�103W)(0.050s)2�����(48.0kg)(0.36m/s�0.00m/s)12.Whenthechainonabicycleispulled�0.45m0.95cm,therearwheelrimmovesadistanceof14cm.Ifthegearhasaradius9.Awinchthat’spoweredbya156-Wmotorof3.5cm,whatistheradiusoftherearliftsacrate9.8min11s.Whatisthemasswheel?ofthecrate?drIMA��e��ed9.8mdrv��rravg�t�11s�0.89m/sredr(3.50cm)(14.0cm)Ifthecrateisinitiallyatrest:r����r�d�0.95cmevvv�i�vf�favg�2�2�52cmvf�2vavg�(2)(0.89m/s)�1.8m/sW�KEm�v2P������tt2t2Pt2Ptm��2���2�v(vf�vi)(2)(156W)(11s)���(1.8m/s)2�1.1�103kg10.Amanexertsaforceof310Nonalevertoraiseacratewithamassof910kg.Iftheefficiencyoftheleveris78percent,whatisthelever’sIMA?Fmg��r����Fe��Fe�e(100)��e(100)(910kg)(9.80m/s2)���310N(100)���78�37Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual627
629Chapter11�KE�W�Fd�(67N)(5.5m)�3.7�102Jpage8721.Acratewithamassof210kgishorizontallySincethecratewasinitiallyatrest,acceleratedbyaforceof95N.Theforce�KE�KEfisdirectedatanupwardanglesothattheKE2Jverticalpartoftheforceis47.5Nandf�3.7�10thehorizontalpartoftheforceis82.3N4.A150-kgroller-coastercarclimbstothe(seethediagrambelow).Ifthecrateistopofa91-m-highhill.Howmuchworkpulled5.5macrossthefloor,whatistheisdoneagainstgravityasthecarisliftedchangeinkineticenergyofthecrate?tothetopofthehill?47.5N95NW�FdF�mg82.3NW�mgd210kg�(150kg)(9.80m/s2)(91m)Smoothfloor�1.3�105JW��KE�Fd5.Apendulumbobwithamassof0.50kg�(82.3N)(5.5m)swingstoamaximumheightof1.0m.What�4.5�102Jisthekineticenergywhenthependulumbobisataheightof0.40m?2.Assumingthatthecratedescribedinprob-Etot�KE�PElem1wasinitiallyatrest,whatisthefinalSinceenergyisconserved,thetotalvelocityofthecrate?energyisconstant.�KE�KEf�KEiWhenthependulumbobisatthetopofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1�mv2theswing,EKEtot�PEatthetopofthef�2fswing.12KEi��2�mviPE�mgh�(0.50kg)(9.80m/s2)(1.0m)Sincethecratewasinitiallyatrest,�4.9JKEi�0.Whenthependulumbobisat0.40m,So,�KE�KE�1�mv2PE�mgh�(0.50kg)(9.80m/s2)(0.40m)f�2f�2.0J2�KE(2)(4.5�102J)vf����m�������210kgKE�Etot�PE�4.9J�2.0J�2.1m/s�2.9J6.Asledanditsrider,withatotalmassof3.Ifthecratedescribedinproblem195kg,areperchedontopofa25-m-tallexperiencedafrictionalforceof15N,hill.Asecondhillis12mtall(seethedia-whatisthefinalkineticenergyofthecrate?grambelow).TheriderisgivenaninitialLetthedirectionofthemotionofthepushproviding3674Jofkineticenergy.cratebepositive.Neglectingfriction,whatisthevelocityattheW��KE�Fdtopofthetopofthe12-m-tallhill?F�FH�Ff�82.3N�(�15N)�67N628SolutionsManualPhysics:PrinciplesandProblems
630Chapter11continuedPE�FghPE3.0�104J2NF������8.6�1025mg�h35m12m9.Thebighillonaroller-coasterrideis91mtall.Ifthemassoftheroller-coastercaranditstworidersis314kgandthemaximumE�KE�PEvelocityreachedbythisroller-coasterrideAtthetopofthe25-m-highhill:is28m/s,howmuchenergywaslosttofriction?KE�3674J2)(25m)Atthetopofthe91-m-highhill:PE�mgh�(95kg)(9.80m/sE�PE�mgh�2.3�104J�(314kg)(9.80m/s2)(91m)E�KE�PE�3674J�2.3�104J�2.8�105J�2.7�104JAtthebottomofthehill:Atthetopofthe12-m-highhill:122)(12m)E�KE��2�mvPE�mgh�(95kg)(9.80m/s�1.1�104J2KE(2)(2.8�105J)v����m�������314kgKE�E�PE�2.7�104J�1.1�104J�42m/sifnoenergyislosttofriction�1.6�104JTheactualKEatthebottomofthehill:2KE(2)(1.6�104J)v������������KE�1�mv2��1�2m95kg���(314kg)(28m/s)22�18m/s5J�1.2�10E�KE�E7.A35-kgchildisridingonaswingthatrisesftoamaximumheightof0.80m.NeglectingE5J�1.2�105Jf�E�KE�2.8�10friction,whatisthechild’sgravitationalpotentialenergyatthetopoftheswing?�1.6�105JWhatisthechild’skineticenergyatthetopoftheswing?10.Adartboardwithamassof2.20kgissuspendedfromtheceilingsuchthatitisPE�mgh�(35kg)(9.80m/s2)(0.80m)initiallyatrest.A0.030-kgdartisthrown�2.7�102Jatthedartboardwithavelocityof1.3m/s.Afterthedarthitsthedartboard,thedartWhentheswingisatitsmaximumandtheboardinitiallymovewithavelocityheight,thevelocityiszero.of0.025m/s.HowmuchkineticenergyisKE��1�mv2�0Jlostinthesystem?2KE�1�m2���1��2i�2dvd2(0.030kg)(1.3m/s)8.AsledanditsriderareperchedatthetopofCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.ahillthatis35mtall.Ifthegravitational�2.5�10�2Jpotentialenergyis3.0�104J,whatisthe12weightofthesledandrider?KEf���2��(md�mb)vfPE�mgh���1��2(0.030kg�2.20kg)(0.025m/s)2Fg�mg�6.97�10�4JPhysics:PrinciplesandProblemsSolutionsManual629
631Chapter11continuedE12.A0.150-kgballthatisthrownatavelocityoflost�KEi�KEf30.0m/shitsawallandbouncesbackinthe�(2.5�10�2J)�(6.97�10�4J)oppositedirectionwithaspeedof25.0m/s.�2.4�10�2JHowmuchworkwasdonebytheball?Conservationofenergy:11.Inaphysicslaboratory,studentscrashcartsWtogetheronafrictionlesstrack.Accordingball��KE�0tothefollowingdata,waskineticenergyWball��KE�KEf�KEiconserved?KE�1�mv2���1��(0.150kg)(30.0m/s)2i�2i2Mass(kg)v(m/s)v(m/s)ifCartA0.250.18�0.21�67.5JCartB0.36�0.200.11KE�1�mv2��1�(0.150kg)(�25.0m/s)2f�2f212�46.9JKE��miA�2AviAWball�KEf�KEi12���2��(0.25kg)(0.18m/s)�46.9J�67.5J�4.0�10�3J��20.6J12KE��miB�2BviB12�����(0.36kg)(�0.20m/s)2�7.2�10�3J12KE��mfA�2AvfA12���2��(0.25kg)(�0.21m/s)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�5.5�10�3J12KE��mfB�2BvfB12�����(0.36kg)(0.11m/s)2�2.2�10�3JIfKEisconserved:KEi�KEfKEi�KEiA�KEiB�4.0�10�3J�7.2�10�3J�11.2�10�3JKEf�KEfA�KEfB�5.5�10�3J�2.2�10�3J�7.7�10�3JKEisnotconserved.630SolutionsManualPhysics:PrinciplesandProblems
632e.298KChapter12TC�TK�273�298�273�25°Cpages872–874f.316K1.ConvertthefollowingCelsiustemperaturestoKelvintemperatures.TC�TK�273�316�273�43°Ca.�196°C4.A9.8-gleadbulletwithamuzzlevelocityTK�TC�273��196�273�77Kof3.90�102m/sisstoppedbyawoodenb.32°Cblock.WhatisthechangeintemperatureofTthebulletifone-fourthofitsoriginalkineticK�TC�273�32�273�305Kenergygoesintoheatingthebullet?c.212°Cv�3.90�102m/sTK�TC�273�212�273�485Kd.�273°CWoodenBulletTblockK�TC�273��273�273�0Km�9.8ge.273°C12TKE���mvK�TC�273�273�273�546K2f.27°C1and��KE�Q�mC�TT4K�TC�273�27�273�300K��1����1��mv2�mC�T422.FindtheCelsiusandtheKelvintempera-turesforthefollowingobjects.�1�v28a.averagebodytemperature�T��C98.6°Fisabout37°C,310K��1��2m/s)28(3.90�10b.hotcoffee���130J/kg�Kabout70°C,343Kc.icedtea�1.5�102Kabout0°C,273K5.Whatisthechangeintemperatureof2.2kgofd.boilingwaterthefollowingsubstancesif8.5�103Jofther-100°C,373Kmalenergyisaddedtoeachofthesubstances?a.ice3.ConvertthefollowingKelvintemperaturesQtoCelsiustemperatures.�T���mCa.4K3J8.5�10����T(2.2kg)(2060J/kg�K)C�TK�273�4�273��269°Cb.25K�1.9KTb.waterC�TK�273�25�273��248°CQc.272K�T���mCCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.TC�TK�273�272�273��1°C8.5�103J����d.373K(2.2kg)(4180J/kg�K)T�0.92KC�TK�273�373�273�100°CPhysics:PrinciplesandProblemsSolutionsManual631
633Chapter12continuedc.steamQ�T���mC8.5�103J����(2.2kg)(2020J/kg�K)�1.9Kd.aluminumQ�T���mC8.5�103J����(2.2kg)(897J/kg�K)�4.3Ke.silverQ�T���mC8.5�103J����(2.2kg)(235J/kg�K)�16Kf.copperQ�T���mC8.5�103J����(2.2kg)(300J/kg�K)�1.0�101K6.A2350-kggranitetombstoneabsorbs2.8�107JofenergyfromtheSuntoCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.changeitstemperaturefrom5.0°Catnightto20.0°Cduringanautumnday.Determinethespecificheatofgranitefromthisinformation.Q�mC�TQ2.8�107J2J/kg�KC���������7.9�10m�T(2350kg)(20.0°C�5.0°C)7.A2.00�103-gsampleofwaterat100.0°Cismixedwitha4.00�103-gsampleofwaterat0.0°Cinacalorimeter.Whatistheequilibriumtemperatureofthemixture?mACA(Tf�TAi)�mBCB(Tf�TBi)�0SinceCA�CBinthiscase,thespecificheatcancelsout.m(2.00kg)(100.0°C)�(4.00kg)(0.0°C)T��ATAi�mBTBi�����f��m2.00kg�4.00kg�33°CA�mB632SolutionsManualPhysics:PrinciplesandProblems
634Chapter12continued8.A220-gironhorseshoeisheatedto825°Candthenplungedintoabucketfilledwith20.0kgofwaterat25.0°C.Assumingthatnoenergyistransferredtothesurroundings,whatisthefinaltemperatureofthewateratequilibrium?WatermT�25.0°CACA(Tf�TAi)�mBCB(Tf�TBi)�0m�20.0kgmT���ACATAi�mBCBTBiHorseshoef�mT�825°CACA�mBCB(0.22kg)(450J/kg�K)(825°C)�(20.0kg)(4180J/kg�K)(25.0°C)����������26°C(0.22kg)(450J/kg�K)�(20.0kg)(4180J/kg�°K)9.Acookadds1.20kgofsoupbonesto12.5kgofhotbrothforflavoring.TheBonestemperaturesofthebonesandthebrothm�1.20kgBrotht�20.0�CT�90.0�Care20.0°Cand90.0°C,respectively.Assumethatthespecificheatofthebrothisthesameasthatofwater.Alsoassumethatnoheatislosttotheenvironment.Iftheequilibriumtemperatureis87.2°C,whatisthespecificheatofthebones?mACA(Tf�TAi)�mBCB(Tf�TBi)�0mC��BCB(Tf�TBi)A��mA(Tf�TAi)(12.5kg)(4180J/kg�K)(87.2°C�90.0°C)�������(1.20kg)(87.2°C�20.0°C)�1.81�103J/kg�K10.A150.0-gcoppercylinderat425°Cisplacedonalargeblockoficeat0.00°C.Assumethatnoenergyistransferredtothesurroundings.Whatisthemassoftheicethatwillmelt?Theenergyformeltingtheicecomesfromthecoolingofthecopper.Q�mC�TThisquantityofenergyisavailabletomelttheice,soQ�miceHfQmC�Tm�����ice�HHff(0.1500kg)(385J/kg�°C)(425°C�0.00°C)������3.34�105J/kgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.0735kgoficePhysics:PrinciplesandProblemsSolutionsManual633
635Chapter12continued11.Howmuchenergyisneededtomeltonetroy13.Acylindercontaining1.00gofwaterattheounce,31.1g,ofgoldatitsmeltingpoint?boilingpointisheateduntilallthewaterturnsintosteam.TheexpandingsteamQ�mHfpushesapiston0.365m.Thereisa215-N�(0.0311kg)(6.30�104J/kg)frictionalforceactingagainstthepiston.Whatisthechangeinthethermalenergy�1.96�103Jofthewater?�U�Q�W12.Tryingtomakeaninterestingpattern,anartistslowlypours1.00cm3ofliquidQ�mHvgoldontoalargeblockoficeat0.00°C.�(1.00�10�3kg)(2.26�106J/kg)Whilebeingpoured,theliquidgoldisatitsmeltingpointof1064°C.Thedensityof�2.26�103Jgoldis19.3g/cm3,anditsspecificheatisW�Fd�(215N)(0.365m)�78.5J128J/kg�K.Whatmassoficewillmeltafter�U�Q�Wallthegoldcoolsto0.00°C?Theenergytomelttheicecomesfrom�2.26�103J–78.5Jtheenergyreleasedwhenthegoldsolid-�2.18�103Jifiesandthenreleasedasthegoldcoolsfromitsmeltingtemperatureto0.00°C.14.Whatisthechangeintemperatureofwaterafterfallingovera50.0-m-tallwaterfall?Qtot�Qsolidification�QcoolingAssumethatthewaterisatrestjustbeforeQsolidification�mHffallingoffandjustafteritreachesthe�(0.0193kg/cm3)(1.00cm3)bottomofthefalls.(6.30�104J/kg)�U�Q–W�U�0andW��KE�PE�mgh�1216JQ�mC�TQcooling�mC�TThus,mC�T�mghCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(0.0193kg/cm3)(1.00cm3)gh(9.80m/s2)(50.0m)(128J/kg�°C)�T�������C4180J/kg�K(1064°C�0.00°C)�0.117K�2628JQ15.Two6.35-kgleadbricksarerubbedagainsttot�1216J�2628J�3844JeachotheruntiltheirtemperaturerisesbyQice�mHf1.50K.HowmuchworkwasdoneontheQbricks?m��iceHf�U�Q�Wand�U�0����3844J1.15�10�2kgW�Q�mC�T3.34�105J/kg�(12.70kg)(130J/kg)(1.50K)�2500J634SolutionsManualPhysics:PrinciplesandProblems
6364.Asshowninthefigurebelow,abubbleofChapter133isreleasedgaswithavolumeof1.20cmpages874–875underwater.Asitrisestothesurface,the1.UseTable13.1toestimatethepressuretemperatureofthebubbleincreasesfrominatmospheres(atm)onaclimberstand-27°Cto54°C,andthepressureiscuttoingatopMt.Everest.Isthismoreorlessone-thirdofitsinitialvalue.Whatisthethanhalfstandardatmosphericpressurevolumeofthebubbleatthesurface?(1.0atm)?4Pa)1.0atm(3�10����5Pa�0.3atm1.0�10Thisislessthanhalfofstandardatmosphericpressure.2.Awomanwearinghighheelsbrieflysupportsallherweightontheheels.Ifhermassis45kgandeachheelhasanareaof1.2cm2,whatpressuredoessheexertonthefloor?T1�27�273�300KFP���TA2�54�273�327KmgP1V1P2V2������AT1T2(45kg)(9.80m/s2)100cm2P����������V�1V1T2(2)(1.2cm2)1m2�T1P2�1.8�103kPaP3)(327K)1(1.20cm���13.Atypicalbrickhasdimensionsof(300K)��3��P120.0cm�10.0cm�5.0cmandweighs3�3.9cm20.0N.Howdoesthepressureexertedbyatypicalbrickwhenitisrestingon5.Asampleofethanegas(molarmass�itssmallestsidecomparetothepressure30.1g/mol)occupies1.2�10�2m3at46°Cexertedwhenitisrestingonitslargestside?and2.4�105Pa.HowmanymolesofethaneFarepresentinthesample?Whatisthemassp��small�Asmallofthesample?20.0N100cm2PV����������n��(10.0cm)(5.0cm)1mRT�4.0�103Pa(2.4�105Pa)(1.2�10�2m3)�����(8.31Pa�m3/mol�K)(319K)Fp��large�Alarge�1.1molofethane20.0N100cm2m�Mn����������(20.0cm)(10.0cm)1m�(30.1g/mol)(1.1mol)�1.00�103Pa�33gCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thepressureisfourtimesaslargewhenthebrickrestsonitssmallestside.Physics:PrinciplesandProblemsSolutionsManual635
637Chapter13continued6.TheconstantRequals8.31Pa�m3/mol�Kasitispresentedintheidealgaslawinthischapter.Onemoleofanidealgasoccupies22.4Latstandardtemperatureandpressure,STP,whichisdefinedas0.00°Cand1.00atm.Giventhisinformation,deducethevalueofRinL�atm/mol�K.PVR���nT(1.00atm)(22.4L)����(1mol)(273K)�0.0821L�atm/mol�K7.Supposethattwolinkedpistonsarebothcylindricalinshape.Showthattheratioofforcesgeneratedisdirectlyproportionaltothesquareoftheradiiofthetwocross-sectionalcircularareas.FF�1��2AA12FF�1��2�r2�r212Fr2�1��1,adirectproportionFr2228.Thecross-sectionalareasofthepistonsFinthesystemshownbelowhavearatioof25to1.Ifthemaximumforcethatcanbeappliedtothesmallpistonis12N,whatisthemaximumweightthatcanbelifted?F2A1Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.F�1�A2(12N)(25)���1�3.0�102N9.Acarofmass1.35�103kgsitsonalargepistonthathasasurfaceareaof1.23m2.Thelargepistonislinkedtoasmallpistonofarea144cm2.Whatistheweightofthecar?Whatforcemustamechanicexertonthesmallpistontoraisethecar?F3kg)(9.80m/s2)g�mg�(1.35�10�1.32�104NFF�1A22�A1mgA��2A1(1.35�103kg)(9.80m/s2)(1.44�10�2m2)������1.23m2�155N636SolutionsManualPhysics:PrinciplesandProblems
638Chapter13continued10.Atwhatdepthinfreshwaterdoesthewater13.Aglassmirrorusedinamountaintopexertapressureof1.00atm(1atm�telescopeissubjecttotemperaturesranging1.013�105Pa)onascubadiver?from�15°Cto45°C.Atthelowesttemper-P��ghature,ithasadiameterof5.1m.IfthecoefficientoflinearexpansionforthisglassPis3.0�10�6°C�1,whatisthemaximumh����gchangeindiameterthemirrorundergoes1.013�105N/m2duetothermalexpansion?�����(1.00�103kg/m3)(9.80m/s2)�L��L�T�10.3m�(3.0�10�6°C�1)(5.1m)(45°C�(�15°C))11.Anicebergfloatsinseawater,partlyunder�9.2�10�4mwaterandpartlyexposed.ShowthatthevalueofVsubmerged/Vtotalequals�ice/�seawater.14.Asshowninthefigurebelow,abimetallicWhatpercentageoftheicebergisexposed?stripismadefromapieceofcopperUse1.03�103kg/m3forthedensityofsea-(��16�10�6°C�1)andapieceofsteelwater,and0.92�103kg/m3forthedensity(��8�10�6°C�1).Thetwopiecesareofice.equalinlengthatroomtemperature.Becausetheicefloats,CopperFbuoyant�Fg�seawaterVsubmergedg��iceVtotalgWoodenVsubmerged�icehandleSteel�����V�totalseawatera.Asthestripisheatedfromroomtem-Thisisageneralresultforfloatingperature,whatistheratioofthechangesolids.inthelengthofthecoppertothatof�0.92�103kg/m3thesteel?��ice����seawater1.03�103kg/m3�L�coppercopperL1�T������0.89�L�steelsteelL1�TSo,89percentissubmergedand�copper11percentisexposed.���steel12.Aconcreteblock(��36�10�6°C�1)of16�10�6°C�1���volume0.035m3at30.0°Ciscooledto8�10�6°C�1�10.0°C.Whatisthechangeinvolume?2���1�V��V�Tb.Howwillthestripbendwhenitisheated�(36�10�6°C�1)(0.035m3)aboveroomtemperature?Whenitis(�10.0°C�30.0°C)cooledbelowroomtemperature?��5.0�10�5m3Whenheated,itbendswithcopperontheoutsideofthearc.Whenitiscooled,thecopperwillbeontheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.insideofthebend.Physics:PrinciplesandProblemsSolutionsManual637
639Chapter13continued15.Afishingline’sleadsinkerhasavolumeof1.40�10�5m3.ThedensityofleadisChapter141.2�104kg/m3.Whatistheapparentpages875–876weightofthesinkerwhenimmersedin1.Whatisthemassofthewatermelonshownfreshwater?Seawaterisslightlydenserthanbelow,ifthespringconstantis128N/m?freshwater.Isthesinker’sapparentweightbiggerorsmallerinseawater?Explain.Fapparent�Fg�Fbuoyant0.48m��leadgV��watergV�gV(�lead��water)�(9.80m/s2)(1.40�10�5m3)(1.2�104kg/m3�1.00�103kg/m3)F�kx�mgkx(128N/m)(0.48m)�1.5Nm�������g9.80m/s2Thebuoyantforceisslightlybiggerinseawater,duetoitsgreaterdensity.�6.3kgThus,theapparentweightisslightly2.Howmanycentimeterswillaspringstretchsmallerthaninfreshwater.whena2.6-kgblockishungverticallyfromaspringwithaspringconstantof89N/m?F�kx�mgmg(2.6kg)(9.80m/s2)x�������k89N/m�0.29mor29cm3.HowmuchelasticpotentialenergydoesCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.aspringwithaconstantof54N/mhavewhenitisstretched18cm?PE�1�kx2���1��(54N/m)(0.18m)2sp�22�0.87J4.Whatistheperiodofthependulumoftheclockbelow?XIIXIIlXIIT�2���IXIII��VIIIIVgVIIVVI0.62m�2�����9.80m/s2�1.6s62cm0.52kg638SolutionsManualPhysics:PrinciplesandProblems
640Chapter14continued5.Aclockpendulumhasaperiodof0.95s.9.GeoisstandingonabreakwaterandheHowmuchlongerwillithavetobetohavenoticesthatonewavegoesbyevery4.2s.aperiodof1.0s?Thedistancebetweencrestsis12.3m.a.Whatisthefrequencyofthewave?lT�2�����g11f������0.24HzT4.2sgT2l��2b.Whatisthespeedofthewave?4�g11l�2�T2)v��f�����T�(12.3m)��4.2�s�2�l1�4�2(T212�2.9m/s�����9.80m/s((1.0s)2�(0.95s)2)4�2�0.024m�2.4cmThependulumwillhavetobe2.4cmlonger.6.Whatisthelengthofapendulumwithaperiodof89.4ms?lT�2�����ggT2(9.80m/s2)(89.4�10�3s)2l�������4�24�2�1.98�10�3m�1.98mm7.AlischoppingwoodacrossaclearingfromSu.Suseestheaxecomedownandhearsthesoundoftheimpact1.5slater.Howwideistheclearing?d�vt�(343m/s)(1.5s)�5.1�102m8.Whenanorchestraistuningup,thefirstviolinistplaysanoteat256Hz.a.Whatisthewavelengthofthatsoundwaveifthespeedofsoundinthecon-certhallis340m/s?v340m/s�������1.3mf256Hzb.Whatistheperiodofthewave?11T������f256HzCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.00391sor3.91msPhysics:PrinciplesandProblemsSolutionsManual639
641Chapter15�(85Hz)��1��1��29.6�m/spage876343m/s1.Soundwavesarebeingusedtodetermine�93Hzthedepthofafreshwaterlake,asshowninthefigurebelow.Ifthewateris25°Cand5.Ifthespeedofawaveona78-cm-longittakes1.2sfortheechotoreturntotheguitarstringisknowntobe370m/s,whatsensor,howdeepisthelake?isthefundamentalfrequency?�1�2L�(2)(0.78m)�1.56mvf��1�2L370m/sDetectorSound���1.56msource�240Hz6.BoatAistravelingat4.6m/s.BoatBismovingawayfromboatAat9.2m/s,as1.2sdepth�vt�(1493m/s)���showninthefigurebelow.Thecaptainof22mboatBblowsanairhornwithafrequency�9.0�10of550Hz.WhatfrequencydoesboatA2.Findthewavelengthofan8300-Hzwaveinhear?Use343m/sforthespeedofsound.copper.vdvsv����f3560m/s���8300HzBoatABoatB�0.43mv�vf��d�d�fs�v�vCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.s3.Janetisstanding58.2mfromNinovan.IfNinovanshouts,howlongwillittake343m/s�4.6m/s�(550Hz)�����343m/s�(�9.2m/s)Janettohearher?Use343m/sforthespeedofsound.�5.3�102Hzd58.2mt�����7.Asubmarineistravelingtowardastationaryv343m/sdetector.Ifthesubmarineemitsa260-Hz�0.170ssoundthatisreceivedbythedetectorasa4.Theengineonamotorcyclehumsat85Hz.262-Hzsound,howfastisthesubmarineIfthemotorcycletravelstowardarestingtraveling?Use1533m/sforthespeedofobserveratavelocityof29.6m/s,whatfre-soundinseawater.quencydoestheobserverhear?Use343m/sv�vf��d�andvforthespeedofsound.d�fs�v�vd�0,sosv�vf��dandvfvd�fs�v�v�d�0,sov�v�s�ss�fd1fd�fs���vfs��1���svs�v�1��f��vd260Hz�(1533m/s)�1����262Hz�12m/s640SolutionsManualPhysics:PrinciplesandProblems
642Chapter15continued8.Theendofapipeisinsertedintowater.Chapter16Atuningforkisheldoverthepipe.Ifthepiperesonatesatlengthsof15cmandpages876–87735cm,whatisthefrequencyofthetuning1.Whatisthedistance,r,betweenthelight-fork?Use343m/sforthespeedofsound.bulbandthetableinthefigurebelow?closedpipe:��2(LB�LA)�(2)(0.35m�0.15m)�0.40mP�2152lmv343m/sf�������0.40mr�8.6�102HzE�180lx9.A350-Hztuningforkisheldovertheendofapipethatisinsertedintowater.Whatisthespacingbetweentheresonancelengthsofthepipeifthespeedofsoundis348m/s?v����andfPE���4�r2L��foraclosedpipe,soB�LA�2P2152lmv348m/sr����������0.98mL������4�E4�(180lx)B�LA�2f(2)(350Hz)�0.50m2.Whatistheluminousfluxofaflashlightthatprovidesanilluminanceof145lxtothesurfaceofwaterwhenheld0.50mabovethewater?PE��4�r2P�4�r2E�4�(0.50m)2(145lx)�4.6�102lm3.Anoverheadlightfixtureholdsthreelight-bulbs.Eachlightbulbhasaluminousfluxof1892lm.Thelightfixtureis1.8mabovethefloor.Whatistheilluminanceonthefloor?P(3)(1892lm)2lxE������1.4�104�r24�(1.8m)24.Whatisthewavelengthinairoflightthathasafrequencyof4.6�1014Hz?c3.00�108m/s�������Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.f4.6�1014Hz�6.5�10�7m�650nmPhysics:PrinciplesandProblemsSolutionsManual641
643Chapter16continued5.Aheliumatomisinagalaxytravelingat6m/sawayfromtheChapter17aspeedof4.89�10Earth.AnastronomeronEarthobservespage877afrequencyfromtheheliumatomof1.Alightrayisreflectedoffaplanemirrorat6.52�1014Hz.Whatfrequencyoflightanangleof25°fromthenormal.Alightisemittedfromtheheliumatom?rayfromanothersourceisreflected54°vfromthenormal.Whatisthedifferenceinfobs�f�1��c��theanglesofincidenceforthetwolightTheyaremovingawayfromeachothersources?sousetheplusform.Difference�54°�25°v�29°f�fobs�1��c��14Hz)4.89�106m/s2.Alightrayisreflectedoffaplanemirror,as�(6.52�10�1���3.00�108m/s�shown.Whatistheangleofreflection?�6.63�1014Hz13°6.Anastronomerobservesthatamolecule�inagalaxytravelingtowardEarthemitsi�90°�angletomirror�90°�13°�77°lightwithawavelengthof514nm.Theastronomeridentifiesthemoleculeasone�r��ithatactuallyemitslightwithawavelength�77°of525nm.Atwhatvelocityisthegalaxymoving?3.Theanglebetweenanincidentandareflected����rayis70.0°.Whatistheangleofreflection?obs���5.14�10�7m�5.25�10�7m�r��iv70.0°����������c2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.���35.0°v��c����8m/s)4.Animageisproducedbyaconcavemirror,��(3.00�10asshown.Whatistheobject’sposition?5.14�10�7m�5.25�10�7m������5.25�10�7m25cm�6.29�106m/s15cmCImagerf���215cm���2�7.5cm642SolutionsManualPhysics:PrinciplesandProblems
644Chapter17continuedfdi9.Aballis6.5mfromaconvexmirrorwithad�o�dmagnificationof0.75.Iftheimageis0.25mi�findiameter,whatisthediameterofthe(7.5cm)(25cm)���actualball?25cm�7.5cmh�1.0�101cmm��iho5.WhatisthemagnificationoftheobjectinThevariablehcanbeusedforanyproblem4?dimensioninplaneandspherical�dmirrors.Inthisproblem,ho�diameterm��idoftheball.oh�25cmh��i��o�m11cm0.25m��2.3���0.756.Iftheobjectinproblem4is3.5cmtall,�0.33mhowtallistheimage?hm��ihohi�mho�(�2.3)(3.5cm)��8.2cmTheimageis8.2cmtall.Thenegativesignmeansitisinverted.7.A6.2-m-tallobjectis2.3mfromaconvexmirrorwitha�0.8-mfocallength.Whatisthemagnification?fdd�oi�do�f(�0.8m)(2.3m)����2.3m�(�0.8m)��0.6m�dm��ido�(�0.6m)���2.3m�0.38.Howtallistheimageinproblem7?hiCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.m��hohi�mho�(0.3)(6.2m)�2mPhysics:PrinciplesandProblemsSolutionsManual643
645Atthewaterandflintglassboundary:Chapter18n��1����2sin�2pages877–8781�sinn11.ApieceofflintglassAir(1.62)(sin38.1°)islyingontopofacon-�sin�1�����48.7°Flintglass1.33tainerofwater(seefigurebelow).WhenaredbeamWater4.Anobjectthatis24cmfromaconvexoflightinairisincidentlensproducesarealimagethatis13cmupontheflintglassatanfromthelens.Whatisthefocallengthofangleof28°,whatisthethelens?angleofrefractionintheflintglass?dido(13cm)(24cm)f�����d13cm�24cmi�don1sin�1�n2sin�2�8.4cmn��1����1sin�12�sinn25.A5.0-cm-tallobjectisplaced16cmfroma(1.0003)(sin28°)convexlenswithafocallengthof8.4cm.�sin�1�����17°1.62Whataretheimageheightandorientation?fd(8.4cm)(16cm)d�o��2.Whentheangleofrefractionintheflinti��d16cm�8.4cmo�fglassofproblem1is22°,whatistheangleofrefractioninthewater?�17.7cmn1sin�1�n2sin�2hi�dim����hdoon��1����1sin�12�sinn�diho�(17.7cm)(5.0cm)2h����i��d16cmo(1.62)(sin22°)�sin�1�����27°��5.5cm1.33Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Theimageisinvertedrelativetothe3.Whenthebeamoflightinproblem1entersobject.theflintglassfromthewater,whatisthemaximumangleofincidenceinthewater6.Anobjectis185cmfromaconvexlenssuchthatlightwilltransmitintotheairabovewithafocallengthof25cm.Whenantheflintglass?Hint:Useanangleofrefractioninvertedimageis12cmtall,howtallisofthelightbeaminairthatisalmost90°.theassociatedobject?Thiswilloccurwhentheangleoffd(25cm)(185cm)d�o��refractionofthelightbeamintheairisi��d185cm�25cmo�falmost90°.Use�2�89.9°.�29cmn1sin�1�n2sin�2hi�dim����hdAttheflintglassandairboundary:oon�d�(185cm)(�12cm)��1����2sin�2h�ohi���1�sinno��d29cm1i(1.0003)(sin89.9°)�77cm�sin�1������38.1°1.62Theobjectis77cmtall.644SolutionsManualPhysics:PrinciplesandProblems
646Chapter18continued7.Whataretheimageheightandorientation9.Aconcavelenswithafocallengthofproducedbythesetupinthefollowingfigure?�220cmproducesavirtualimagethatis36cmtall.Whentheobjectisplaced128cmfromthelens,whatistheObjectmagnification?fd(�220cm)(128cm)d�o���5.0cmi��d128cm�(�220cm)o�f��81cmF�d�(�81cm)m���i���0.6310.0cmd128cmo15.0cmfd(15.0cm)(10.0cm)d�o���i��d10.0cm�15.0cmo�f��3.0�101cmh�dm���i�ihdoo�d�(�3.0�101cm)h�iho���i��d10.0cmo�15cmTheimageisuprightrelativetotheobject.8.Aconvexlenscanbeusedasamagnifyingglass.Whenanobjectthatis15.0cmfromthelenshasanimagethatisexactly55timesthesizeoftheobject,whatisthefocallengthofthelens?�dm��idodi��mdo��(55)(15.0cm)��825cmdf��idodi�do(�825cm)(15.0cm)����(�825cm)�(15.0cm)�15.3cmCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual645
6473.Lightwithawavelengthof454.5nmpassesChapter19throughtwoslitsthatare95.2cmfromapages878–879screen.Thedistancebetweenthecenters1.Aphysicsstudentperformsadouble-slitofthecentralbandandthefirst-orderbanddiffractionexperimentonanopticalbench,is15.2mm.Whatistheslitseparation?asshowninthefigurebelow.Thelightxd����fromahelium-neonlaserhasawavelengthLof632.8nm.Thelaserlightpassesthrough�Ld���twoslitsseparatedby0.020mm.Whatisxthedistancebetweenthecentersofthe(4.545�10�7m)(0.952m)centralbandandthefirst-orderband?�����0.0152mScreen�2.85�10�5mLaserDiffractiongrating4.Whatcoloroflightwouldbereflectedfromthesoapywaterfilmshowninthefigurebelow?50.0cmAir150.0cmSoapywaterL�150.0cm�50.0cm76.1nm�100.0cmnSW�1.33xdAir����L1��L2d��m������x���2nswd(6.328�10�7m)(1.000m)Form�0,2d�1����.�������5m2nsw2.0�10�3.2�10�2m�3.2cm��4dnswCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(4)(76.1nm)(1.33)2.Alaserofunknownwavelengthreplaces�405nmthehelium-neonlaserintheexperimentdescribedinproblem1.ToobtainthebestThelightisvioletincolor.diffractionpattern,thescreenhadtobe5.A95.7-nmfilmofanunknownsubstanceismovedto104.0cm.Thedistancebetweenabletoprevent555-nmlightfrombeingthecentersofthecentralbandandthefirst-reflectedwhensurroundedbyair.Whatisorderbandis1.42cm.Whatwavelengthoftheindexofrefractionofthesubstance?lightisproducedbythelaser?1�L�104.0cm�50.0cm2d��m������2nsub�54.0cm1�Form�0,2d�����.xd2n����subL�(1.42�10�2m)(2.0�10�5m)nsub��4d������0.540m555nm����5.3�10�7m�530nm(4)(95.7nm)�1.45646SolutionsManualPhysics:PrinciplesandProblems
648Chapter19continued6.Anoilfilm(n�1.45)onthesurfaceofa2�L2x�1�wpuddleofwateronthestreetis118nmthick.Whatfrequencyoflightwouldbe(2)(6.85�10�7m)(1.1m)����reflected?2.5�10�5m1��0.063m2d��m������2noil9.Thewidthofthecentralbrightbandofa1�Form�0,2d�����.diffractionpatternis2.9cm.Laserlight2noilofunknownwavelengthpassesthrougha��4dnoilsingleslitthatis0.042mmwideandonto�(4)(118nm)(1.45)ascreenthatis1.5mfromtheslit.Whatisthewavelengthofthelight?�685nmc2�L����2x1��wfc2x1wf�������2L3.00�108m/s(0.029m)(4.2�10�5m)�������6.85�10�7m(2)(1.5m)�4.38�1014Hz�4.1�10�7m7.Violetlight(��415nm)fallsonaslitthat10.Adiffractiongratinghas13,400linesperis0.040mmwide.Thedistancebetweeninch.Whatistheslitseparationdistance?thecentersofthecentralbrightbandand(Use1in�2.54cm)thethird-orderdarkbandis18.7cm.What1in2.54cm1md�����������isthedistancefromtheslittothescreen?13,400lines1in100cmmL��1.90�10�6m/linex�m�wxmw11.Lightfromahelium-neonlaser(��L��m�632.8nm)passesthroughthediffraction(0.187m)(4.0�10�5m)gratingdescribedinproblem10.Whatis����(3)(4.15�10�7m)theanglebetweenthecentralbrightlineandthefirst-orderbrightline?�6.0m��dsin�8.Redlight(��685nm)fallsonaslitthatis�1���sin���0.025mmwide.Thedistancebetweenthedcentersofthecentralbrightbandandthe�16.328�10�7msecond-orderdarkbandis6.3cm.Whatis�sin����1.90�10�6mthewidthofthecentralband?�19.5°mL�x�m�wxL��mwm�Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.(0.063m)(2.5�10�5m)����(2)(6.85�10�7m)�1.1mPhysics:PrinciplesandProblemsSolutionsManual647
649Chapter19continued12.Adiffractiongratingwithslitsseparatedby3.40�10�6misilluminatedbylightwithawavelengthof589nm.Theseparationbetweenlinesinthediffractionpatternis0.25m.Whatisthedistancebetweenthediffractiongratingandthescreen?��dsin��1���sin���d�15.89�10�7m�sin����3.40�10�6m�9.98°xtan����LxL���tan�0.25m���tan9.98°�1.4mCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.648SolutionsManualPhysics:PrinciplesandProblems
650Chapter20page8791.Themagnitudeofacharge,q,istobedeter-minedbytransferringthechargeequallytotwopithballs.Eachofthepithballshasamassofm,andissuspendedbyaninsulatingthread��oflengthl.Whenthechargeistransferred,thepithballsseparatetoformanequilibriuminlwhicheachthreadformsanangle,�,withthevertical.a.Drawaforcediagramshowingtheforcesthatareactingontherightmostpithball.ddFT�FEFgwhere:FT�threadtensionFE�electrostaticforceFg�gravitationalforceb.Deriveanexpressionforqasafunctionof�,m,andl.Sincethesystemisinequilibrium,thenethorizontalandverticalforcesmustbezero.�FTsin��FE�0FTcos��Fg�0RearrangeandsubstituteFEandFg.q2q��2��q2F�AqB�Tsin��FE�K(2d)2�K�4d2�K16d2FTcos��Fg�mgCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.DividethefirstequationbythesecondtoeliminateFT.q2sin����tan��K�cos�16mgd2Physics:PrinciplesandProblemsSolutionsManual649
651Chapter20continuedFromthediagram,d�lsin�.Substitutefordandsolveforq.16mgl2sin2�tan�q2����Kmgtan�q�4lsin������Kc.Useyourderivedexpressiontodeterminethevalueofqwhen��5.00°,m�2.00g,andl�10.0cm.(2.00�10�3kg)(9.80m/s2)(tan5.0°)q�(4)(10.0�10�2m)(sin5.0°)���������(9.0�109N�m2/C2)�1.52�10�8C2.Asshowninthefigurebelow,fourcharges,eachwithchargeq,aredistributedsym-metricallyaroundtheorigin,O(0,0),atA(1.000,0),B(0,1.000),C(�1.000,0),andD(0,�1.000).Findtheforceonafifthcharge,qT,locatedatT(5.000,0).y(m)B0CATx(m)DBecauseofsymmetry,theforcecomponentsonchargeTinthedirectionofthey-axiscancel,andonlythex-directionforcesneedtobecomputed.FT,x�FAT,x�FBT,x�FCT,x�FDT,xCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.1cos�B1cos�D�Kqq����T��AT�2����BT�2�CT�2�DT�2�5���1�2�52�11�KqqT��16��(2)��2�52��36��1�0.1657KqqTN3.Considerthatthefourchargesinthepreviousproblemarenowcombinedintoasinglecharge,4q,locatedattheorigin.WhatistheforceonchargeqT?(4q)(qT)4K��52�KqqT��25���0.1600KqqTNAchargeuniformlyspreadoverasphericalsurfacemaybetreatedasifallofthechargeisconcentratedatthesphere’scenter.Thepreviousproblemisatwo-dimensionalapproximationofthiscondition.650SolutionsManualPhysics:PrinciplesandProblems
652Chapter21F�qE�(0.5�10�7C)(6.2�104N/C)pages879–8801.Whatarethemagnitudeandthesignofa�3.1�10�3NpointchargethatexperiencesaforceofThedirectionisoppositethatof0.48Neastwhenplacedinanelectrictheelectricfieldbecausethechargefieldof1.6�105N/Cwest?�3N,isnegative.So,E�3.1�10q�F�����0.48N3.0�10�6C15°southofwest�E1.6�105N/CBecausetheforceexertedonthecharge4.Bywhatpercentmustthedistancefromaisoppositethedirectionoftheelectricpointchargeincreaseinordertohaveafield,thechargemustbenegative.reductionintheelectricfieldstrengthby40percent?2.Atestchargeof�1.0�10�6C,locatedatTheelectricfieldstrengthofapointthepointT(0,1)m,experiencesaforceofcharge,0.19Ndirectedtowardtheorigin,alongtheqy-axis,duetotwoidenticalpointchargesE�K�2,rlocatedatA(�1,0)mandB(1,0)m.isinverselyproportionaltothesquare�yofthedistancefromthecharge.Er2��1��2qT(0,1)Er2T21Eqqr2���1r2AB2E1�x2A(�1,0)B(1,0)Er��1r2���E12Inthiscase,E2�(1�0.40)E1�0.60E11Then,r��r2���0.601�1.2r1a.WhatisthesignofthechargesatAandB?Thedistancemustincreaseby30percent.ThechargesatAandBmustbepositivetocauseanattractiveforce5.Aparticleofmassm�2.0�10�6kgisonthetestcharge.inacircularorbitaboutapointcharge.b.WhatarethemagnitudeanddirectionThecharge,q,is3.0�10�5CandisataoftheelectricfieldatT?distanceofr�20.0cm.F0.19NE������q1.0�10�6CE�1.9�105N/CFEThedirectionisoppositetheforcebecauseitisanegativecharge.So,20.0cmqE�1.9�105N/C,awayfromtheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.origin.3.Atestchargeof�0.5�10�7Cisplacedinanelectricfieldof6.2�104N/C,directeda.Whatistheelectricfieldstrengthat15°northofeast.Whatistheforceexperi-allpointsontheorbitaroundtheencedbythecharge?pointcharge?Physics:PrinciplesandProblemsSolutionsManual651
653Chapter21continuedSincetheorbitiscircular,theTheelectricfieldstrengthisthesumdistanceoftheparticlefromtheoftwocomponents,oneduetoeachpointchargeisconstant.Fromcharge,bothpointingtowardtheExampleProblem2,theelectricnegativecharge.Atthemidpoint,fieldstrengthdependsonlyonthethemagnitudesofthecomponentdistanceandthecharge,andisfieldstrengthsareequal.givenby2Kq8KqqE�Eq�E�q����r2E�K���r��2r22SolveforqintermsofE.9N�m2/C2)3.0�10�5C�(9.0�10��(0.200�m)2�2(4.8�104N/C)(0.50m)2Erq������8K(8)(9.0�109N�m2/C2)�6.8�106N/C,radiallyoutwardatallpointsontheorbit�1.7�10�7Cb.Consideringonlyelectrostaticforces,7.Apithballweighing3.0�10�2Ncarriesawhatcharge,q,ontheparticleischargeof�1.0�10�6C.Thepithballisrequiredtosustainanorbitalperiodof3.0�10�3s?placedbetweentwolarge,parallel,metalplates,thatareseparatedby0.050m.WhatTheelectrostaticforceFEmustbeisthepotentialdifference,�V,thatmustbetowardthepointchargetoaccountappliedinordertosuspendthepithballforthecentripetalaccelerationofbetweentheplates?theparticleinorbit.Therefore,theparticlechargemustbenegative.�V�EdTheforcerequiredtokeeptheFEd���particleinorbitis(seeChapter6,qMotioninTwoDimensions):(3.0�10�2N)(0.050m)4�2r�����1.0�10�6CF��,radiallyinward.E�mac�mT23VCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�1.5�10Thechargeontheparticlemustthenbe8.Theelectricfieldstrength,definedasaforceFEperunitcharge,hastheunitsnewtonsperq���Ecoulomb,N/C.Theformulaforelectric�4�2rmpotentialdifference,�V�Ed,however,���ET2suggeststhatEalsocanbeexpressedasvoltspermeter,V/m.�4�2(0.200m)(2.0�10�6kg)�����(6.8�106N/C)(3.0�10�3s)2a.Byanalysisoftheunits,showthatthesetwoexpressionsfortheunitsofelectric��2.6�10�7Cfieldstrengthareequivalent.6.TwochargesofequalmagnitudeandVJ/C(N�m)/CN�����������mmmCoppositesignareplaced0.50mapart.Theelectricfieldstrengthmidwaybetweenthemb.SuggestareasonwhyV/misoftenais4.8�104N/Ctowardthenegativecharge.moreusefulwaytoexpresselectricWhatisthemagnitudeofeachcharge?fieldstrength.Inpractice,electricpotentialdiffer-�qE�qencesanddistancesaremucheasierrrtomeasurethanforcesoncharges.22652SolutionsManualPhysics:PrinciplesandProblems
654Chapter21continued9.Supposeyouhavetwoparallel,metalplates13.Anoildropweighing7.5�10�15Ncarriesthathaveanelectricfieldbetweenthemofthreeexcesselectrons.strength3.0�104N/C,andare0.050ma.Whatpotentialdifferenceisrequiredapart.Considerapoint,P,located0.030mtosuspendthedropbetweenparallelfromplateA,thenegativelychargedplate,platesseparatedby2.3cm?whenansweringthefollowingquestions.�Va.WhatistheelectricpotentialatPFg�FE�qE�neE�ne�drelativetoplateA?Fdg�V4V/m)(0.030m)�V���PA�(3.0�10ne�9.0�102V(7.5�10�15N)(2.3�10�2m)�����(3)(1.60�10�19C)b.WhatistheelectricpotentialatPrelativetoplateB,thepositivelychargedplate?�3.6�102V�V4V/m)(0.020m)b.Iftheoildroppicksupanotherelectron,PB��(3.0�10byhowmuchmustthepotentialdiffer-��6.0�102Vencebetweentheplatesbereducedtomaintaintheoildropinsuspension?10.Acertain1.5-Vsize-AAbatteryhasastorageFcapacityof2500C.Howmuchworkcangd�V��thisbatteryperform?neW�q�V�(2.5�103C)(1.5V)Sothepotentialdifferenceis3Jinverselyproportionaltothe�3.8�10numberofexcesselectrons.11.Inavacuumtube,electronsacceleratefrom�V2n1�����thecathodeelementtotheplateelement,�V1n2whichismaintainedatapositivepotentialn�V��1�Vwithrespecttothecathode.Iftheplatevolt-2�n12ageis�240V,howmuchkineticenergy��3�(3.6�102V)�2.7�102Vhasanelectronacquiredwhenitreaches��4theplate?Reductionof90VThekineticenergygainedbyanelectronisthesameasthepotentialenergylost14.Achargeof2.00�10�6Cismovedagainstbytheelectronasitmovesthroughtheaconstantelectricfield.If4.50�10�4Jofpotentialdifferenceof240V.workisdoneonthecharge,whatisthe�KE��W��e�Vpotentialdifferencebetweentheinitial�(1.60�10�19C)(240V)andthefinallocationsofthecharge?�3.8�10�17JWq4.50�10�4J�V������q2.00�10�6C12.Anoildropwithfiveexcesselectronsissus-�225Vpendedinanelectricfieldof2.0�103N/C.Whatisthemassoftheoildrop?15.CapacitorsC1�220�FandC2�470�FareFg�mg�FE�qE�neEconnectedacrossa48.0-VelectricpotentialCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Fdifference.gneEm�����gga.Whatarethecharges,q1andq2,oneachofthecapacitors?(5)(1.60�10�19C)(2.0�103N/C)�����2q9.80m/sC����V�1.6�10�16kgPhysics:PrinciplesandProblemsSolutionsManual653
655Chapter21continuedq�6F)(48.0V)e.Basedonyourresponsestotheabove,1�C1�V�(220�10makeaconjectureconcerningthe�1.1�10�2Cequivalentcapacitanceofasystemofq�6F)(48.0V)capacitors—allofwhichareconnected2�C2�V�(470�10acrossthesamepotentialdifference.�2.3�10�2CTheequivalentcapacitanceisb.Whatisthetotalcharge,qT,onboththesumofalloftheindividualcapacitors?capacitances.qT�q1�q216.Anew90.0-Vbatterywithastoragecapacity�C1�V�C2�Vof2.5�104Cchargesa6800-�Fcapacitor�(CwiththeswitchinpositionA.Thenthe1�C2)�VswitchisthrowntopositionBtodischarge�(220�10�6F�470�10�6F)thecapacitor.(48.0V)�3.3�10�2CBAc.Repeatstepsaandbforanewpotentialdifference,�v��96.0V.Discharge�circuit90.0V�6F)(96.0V)q1��C1�V��(220�10��2.1�102Cq�6F)(96.0V)a.Howmanytimescanthiscyclebe2��C2�V��(470�10�4.5�10�2Crepeatedbeforethebatteryiscompletelydischarged?qT��q1��q2�Whenthecapacitoriscompletely�(Ccharged,itcontains1�C2)�V�(220�10�6F�470�10�6F)q�6�F)(90.0V)c�C�V�(6800�10(96.0V)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.61C�6.6�10�2CThenumberofcyclesNisd.Nowconsiderthetwocapacitorsasasystem.Whatwouldbeasingleequiva-2.5�104CN���lentcapacitor,C0.61C/cycleeq,thatcouldreplaceC1andC2,andbecapableofyieldingthe�4.1�104cyclessameresults?b.IfthecapacitordischargeoccursinLetCeq�C1�C2�690�F120ms,whatistheaveragepowerdissipatedinthedischargecircuitThen,duringonecycle?qT�Ceq�VTheenergystoredinthefully�(690�10�6F)(48.0V)chargedcapacitorequalstheworkperformedtostorethecharge.�3.3�10�2CW�qandc�VTheaveragepowerdissipatedqT��Ceq�V�equalsthetotalenergydissipated�(690�10�6F)(96.0V)dividedbythetimerequired.q�6.6�10�2CP��E���W���c�Vtttyieldingsimilarresultsaspreviously.654SolutionsManualPhysics:PrinciplesandProblems
656Chapter21continued(0.61C)(90.0V)���Chapter220.12s2Wpages881–882�4.6�101.Adecorativelightbulbratedat7.50Wdraws60.0mAwhenlit.Whatisthe17.A0.68-�Fcapacitorcarriesachargeononeplateof1.36�10�5C.Whatisthepotentialvoltagedropacrossthebulb?differenceacrosstheleadsofthiscapacitor?P�VIqP(7.50W)C���V�������125V�VI(60.0�10�3A)q1.36�10�5C2.A1.2-Vnickel-cadmiumbatteryhasa�V������C0.68�10�6Fratedstoragecapacityof4.0�103mAh�2.0�101V(milliamp-hours).a.Whatisthebatterychargecapacityincoulombs?Hint:1C�1As.3mAh)1A3600sq�(4.0�10�������1000mA1h�1.4�104A�s�1.4�104Cb.Howlongcanthisbatterysupplyacurrentof125mA?q�It4.0�103mAht����32h125mA3.Aheatingelementofanelectricfurnaceconsumes5.0�103Wwhenconnectedacrossa240-Vsource.Whatcurrentflowsthroughtheelement?P�VIP5.0�103WI������21AV240V4.Thecoldfilamentresistanceofalightbulbis20.0.Thebulbconsumes75Wwhenitisoperatingfroma120-Vsource.Bywhatfactordoesthestart-upcurrentinthebulbexceedtheoperatingcurrent?VI��start�RPI��operate�VVI�R�V2(120V)2�sta�rt�������Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�Ioperate�P�RP(20.0�)(75W)V�9.6Thestart-upcurrentis9.6timeslargerthantheoperatingcurrent.Physics:PrinciplesandProblemsSolutionsManual655
657Chapter22continued5.Inthecircuitshownbelow,apotentiometer8.Modifythediagramofthepreviousproblemisusedtovarythecurrenttothelamp.Iftoincludeanammeterandavoltmetertotheonlyresistanceisduetothelamp,whatmeasurethevoltagedropacrossthe680-isthecurrentinthecircuit?resistor.II220��12V90.0V��Rlamp�20.0AVV12VII�������0.60AR20.0�lamp6806.Anelectrictoasterconsumes1875Winoperation.Ifitispluggedintoa125-V9.Ifthetotalresistanceinthecircuitsource,whatisitsresistance?inproblem8is9.0�102,whatwouldtheammeterandthevoltmeterindicate?V2P���AmmeterreadingisRV2(125V)2VR�������8.33�I���P1875WR90.0V����0.10A7.Drawacircuitdiagramtoincludea90.0-V9.0�102�battery,a220-resistor,anda680-Voltmeterreadingisresistorinseries.ShowthedirectionofV�IRconventionalcurrent.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�(0.10A)(680�)�68VI22010.Anelectricmotorwithaloaddelivers5.2hptoitsshaft(1hp�746W).Under�theseconditions,itoperatesat82.8percent90.0V�efficiency.(Efficiencyisdefinedastheratioofpoweroutputtopowerinput.)a.Howmuchcurrentdoesthemotordrawfroma240-Vsource?IPoutputEfficiency����0.828Pinput680PoutputP��inputEfficiencyI������VV(5.2hp)(746W/hp)���0.828�240V�2.0�101A656SolutionsManualPhysics:PrinciplesandProblems
658Chapter22continuedb.Whathappenstotheremainingb.Assumeabulbhasalifetimeof17.2percentoftheinputpower?1.0�103handanelectricenergycostItisprimarilydissipatedasI2Rof$0.12/kWh.Howmuchlessdoeslossesinthemotorwindings.the55-WbulbcosttooperateoverUltimately,thisenergyisconverteditslifetime?tothermalenergyandmustbeThe60.0-Wbulbcostsremovedfromthemotorbyfans(0.0600kW)(1.0�103h)($0.12/kWh)orothermeans.�$7.20The55-Wbulbcosts11.Anindustrialheatingprocessusesacurrent(0.055kW)(1.0�103h)($0.12/kWh)of380Asuppliedat440-Vpotential.�$6.60a.WhatistheeffectiveresistanceoftheThedifferenceincostisheatingelement?$7.20�$6.60�$0.60R��V���440�V�1.2�c.IsmostofthecostsavingsduetoI380Ahigherbulbefficiency,orduetotheb.Howmuchenergyisusedbythisconsumer’swillingnesstoacceptlowerprocessduringan8-hshift?lightoutput?E�Pt�VItMostofthesavingsisduetoa3600swillingnesstoacceptlowerlight�(440V)(380A)(8h)����1houtput.Ifthe60.0-Wbulbcould�5�109Jbemadetooutput800.0Im,itscostwouldbe800.012.An8.0-electricheateroperatesfrom����($7.20)�$6.86,resultingina840.0a120-Vsource.savingsof$0.26forthe55-Wbulb.a.HowmuchcurrentdoestheheaterSoofthe$0.60savingsoverthebulbrequire?lifetime,only$0.26,or43percent,isduetohigherefficiency.V120VI�������15AR8.0�14.BywhatfactorwouldtheI2Rlossintrans-b.Howmuchtimedoestheheaterneedto4Jofthermalenergy?missionwiresbereducedifthetransmissiongenerate2.0�10voltagewereboostedfrom220Vto22kV?E�Pt�VItAssumethattherateofenergydeliveredis4unchanged.E2.0�10Jt�������11sVI(120V)(15A)Thepowerrequiredisthesame.Thecurrent,however,wouldbereducedby13.Amanufactureroflightbulbsadvertisesthatthesamefactorthatthevoltagewasits55-Wbulb,whichproduces800.0lmofboosted,102.TheI2Rlosswouldbelightoutput,providesalmostthesamelightreducedbyafactorof104becausetheasa60.0-Wbulbwithanenergysavings.currentissquared.The60.0-Wbulbproduces840.0lm.15.Theelectric-utilityinvoiceforahouseholda.Whichbulbmostefficientlyconvertsshowsausageof1245kWhduringaelectricenergytolight?certain30-dayperiod.WhatistheaverageCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.800.0lmThe55-Wbulbproduces��,powerconsumptionduringthisperiod?55Wor14.5lm/W.The60.0-WbulbE1.245�106Wh1d840.0lmP������������produces��,or14.0lm/W.t30d24h60.0WThe55-Wbulbismoreefficient.�2�103WPhysics:PrinciplesandProblemsSolutionsManual657
659Chapter23b.Whatisthevoltagedropinthe400-resistor?pages882–884V1.Aseriescircuitcontainsa47-resistor,an400��IR400�82-resistor,anda90.0-Vbattery.What�(0.1000A)(400.0�)resistance,R3,mustbeaddedinseriesto�40.00Vreducethecurrentto350mA?V4.ShowthatthetotalpowerdissipatedinI�source��acircuitofseries-connectedresistorsisRP�I2R,whereRistheequivalentresistance.VR�source��IThetotaldissipatedpowerisequaltothesumofthepowerdissipationsin90.0V���0.350Aeachoftheresistors.�257�P�P1�P2�…Foraseriescircuit,R�R1�R2�R3�I2R2R1�I2�…R3�R�R1�R2�I2(R1�R2�…)�257��47��82��I2R�128�5.Inanexperiment,threeidenticallightbulbs2.Whatistheminimumnumberof100.0-areconnectedinseriesacrossa120.0-Vresistorsthatmustbeconnectedinseriessource,asshown.Whentheswitchisclosed,togetherwitha12.0-batterytoensureallofthebulbsareilluminated.However,thatthecurrentdoesnotexceed10.0mA?whentheexperimentisrepeatedthenextVsourceday,bulbsAandBareilluminatedbrighterI���,whereI0.0100ARthannormal,andbulbCisdark.Avolt-Letnequalthenumberof100.0-�meterisusedtomeasurethevoltagesintheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.resistors.Thus,forthisseriescircuit,circuitasshown.Thevoltmeterreadingsare:R�100.0nV1�120.0VV12.0V2�60.0V0.0100A��VR3�0.0V12.0V0.0100A��(BulbA)(BulbB)(BulbC)100.0nRARBRC12.0n���12.0(0.0100)(100.0)Theremustbeatleast12resistors.120.0VV1V2V33.A120.0-generatorisconnectedinserieswitha100.0-resistor,a400.0-resistor,anda700.0-resistor.a.Howmuchcurrentisflowinginthea.Whathashappenedinthiscircuit?circuit?BulbChasdevelopedashortcircuitVI�source��initsbaseandthus,nocurrentflowsRthroughitsfilamentanditremains120.0V�����dark.Theshortactsasazeroresis-100.0��400.0��700.0�tanceandallowsthecircuitcurrent�0.1000A658SolutionsManualPhysics:PrinciplesandProblems
660Chapter23continuedtoflow.Themeasurementsconfirm7.Tworesistorsareconnectedinseriesacrossthattheavailablevoltageisdroppeda12.0-Vbattery.Thevoltagedropacrossacrosstheremainingtwobulbs.oneoftheresistorsis5.5V.b.ExplainwhybulbsAandBarebrightera.Whatisthevoltagedropacrossthethannormal.otherresistor?Thevoltagedropacrosseachbulb12.0V�5.5V�6.5V120.0Vincreasedfrom���40.00V,b.Ifthecurrentinthecircuitis5.0mA,3120.0Vwhatarethetworesistorvalues?to���60.00V.Thepower22VVdissipatedineachbulb,P��R,R���Ihasincreasedbecauseofthe5.5VincreasedV.R��1�0.0050Ac.Istheremoreorlesscurrentflowing�1100�nowinthecircuit?6.5VMorecurrentflowsthroughtheR2��0.0050�Acircuit.Theequivalentresistanceof�1300�twobulbsandashortcircuitislowerthanthatofthreebulbs.This8.Inproblem7,thespecificationsforthelowerequivalentresistanceresultsresistorsstatethattheirresistancemayvaryinanincreasedcurrent.fromthelistednominalvalue.Ifthepossi-blerangesofactualresistancevaluesare6.Astringofholidaylightshas25identicalasfollows,1050Rbulbsconnectedinseries.Eachbulbdissi-11160,and1240Rpates1.00Wwhenthestringisconnected21370,whatisthepossi-bleminimumandmaximumvalueofthetoa125-Voutlet.nominal5.5-Vvoltagedrop?a.HowmuchpowermustbesuppliedbyConstructatabletodeterminethevolt-the125-Vsource?agedropsresultingfromtheextremeP�(25bulbs)(1.00W/bulb)valuesoftheresistors.Thevoltagedrop�25.0Wiscalculatedusingtheequation12Rb.Whatistheequivalentresistanceof��1.R�Rthiscircuit?12V2P��RResistorR1ResistorR2VoltageDropk�k�(V)V2(125V)2R���P�25.0�W�625�1.051.245.5c.Whatistheresistanceofeachbulb?1.051.375.2Becausethebulbsareinseries,1.161.245.8R�R���625���25.0�1.161.375.5bulb�2525Thevoltagedropwillrangefrom5.2Vd.Whatisthevoltagedropacrosseachto5.8V.bulb?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Becausethebulbsareinseries,V125VV������5.00Vbulb�2525Physics:PrinciplesandProblemsSolutionsManual659
661Chapter23continued9.Avoltage-dividercircuitisconstructedwithb.Whatistheoperatingresistanceofeachapotentiometer,asshownbelow.Thereareofthebulbs?twofixedresistancesof113kand294k.SincethebulbsareconnectedTheresistanceofthepotentiometercaninparallel,thesamevoltageisrangefrom0.0to100.0k.connectedacrosseachofthem.V2P��R113kV2R���P�100.0V100.0k2�(125V)R���208�75�75.0WVout294k(125V)2R���625�25�25.0W�c.Thebulbsarerewiredinseries.Whatisa.WhatisVoutwhenthepotentiometerthedissipatedpowerineachbulb?isatitsminimumsettingof0.0?Whichbulbisthebrightest?Vout�VminThecurrentinthecircuitisnow:294k�Vsource�������I���294k��100.0k��113k�R(100.0V)V���RR25�75�58.0V125Vb.WhatisV���outwhenthepotentiometer833�isatitsmaximumsettingof100.0k?�0.150AVout�VmaxThepowerdissipatedineachbulbis:294k��100.0k�P2R2(208�)�������75�I75�(0.150A)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.294k��100.0k��113k�(100.0V)�4.68WP2R2(625�)�77.7V25�I25�(0.150A)c.Whatpotentiometersettingisrequired�14.1WtoadjustVouttoexactly65.0?The25-Wbulbisthebrightest.ThesettingisthesameastheratiooftherangefromV11.A10.0-Vbatteryhasaninternalresistanceminto65.0Vtothetotalavailablerange.of0.10.Theinternalresistancecanbemodeledasaseriesresistor,asshown.(65.0V)�Vmin65.0V�58.0V�����Vmax�Vmin77.7V�58.0VRI�0.10�35.5%10.Twolightbulbs,oneratedat25.0Wandoneratedat75.0W,areconnectedin�parallelacrossa125-Vsource.10.0VVRL�a.Whichbulbisthebrightest?The75.0-Wbulbdissipatesthemostpowerandthereforeburnsthebrightest.BatteryLoad660SolutionsManualPhysics:PrinciplesandProblems
662Chapter23continueda.Deriveanexpressionforthebattery211�V�����…�terminalvoltage,V,asafunctionofR1R2thecurrent,I.V2��voltagerise�sumofvoltagedropsR10.0�IRI�V13.AholidaylightstringoftenbulbsisV�10.0�IRIequippedwithshuntsthatshortoutthe�10.0–0.10Ibulbswhenthevoltagedropincreasestolinevoltage,whichhappenswhenabulbb.Createagraphofvoltageversuscurrentburnsout.Eachbulbhasaresistanceforacurrentrangeof0.0to1.0A.of200.0.Thestringisconnectedtoa(1.0A,9.9V)householdcircuitat120.0V.Ifthestring10.0isprotectedbya250.0-mAfuse,howmany9.9bulbscanfailwithoutblowingthefuse?Thestringwilloperateaslongasthecurrentislessthan250.0mA.VI���Voltage(V)RV0.250A��nRbulb000.51.0120.0V0.250A��Current(Amps)(n)(200.0�)c.WhatvalueofloadresistorRn���120.0VLneedsto(0.250A)(200.0�)beplacedacrossthebatteryterminalstogiveacurrentof1.0A?n2.4VVThestringwilloperatewithatleastI���sourcesour�ce�RR�Rthreegoodbulbs,ornomorethanILsevenfailedbulbs.Vsource10.0VR���R���0.10�L�II�1.0A14.A60.0-Wlightbulbanda75.0-Wlightbulb�9.9�areconnectedinserieswitha120-Vsource.d.HowdoestheV-Ifunctiondifferfroma.Whatistheequivalentresistanceofthatofanidealvoltagesource?thecircuit?AnidealvoltagesourceprovidesV2P��thespecifiedpotentialdifferenceRregardlessoftheamountofcurrent2V2(120V)drawnfromit.R�����P60.0W�75.0W12.Showthatthetotalpowerdissipatedina�1.1�102�circuitofparallel-connectedresistorsis:b.Supposean1875-WhairdryerisnowV2P���,whereRistheequivalentresistance.pluggedintotheparallelcircuitwiththeRlightbulbs.WhatisthenewequivalentThetotaldissipatedpowerisequaltoresistanceofthecircuit?Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.thesumofthepowerdissipationsinV2(120V)2eachoftheresistors.R�������P60.0W�75.0W�1875WP�P1�P2�…�7.2�V2V2P�����…RR12Physics:PrinciplesandProblemsSolutionsManual661
663Chapter23continued15.WhatistheequivalentresistanceoftheChapter24followingresistornetwork?pages884–88529.4k25.5k1.ThemagneticfieldofEarthresemblesthefieldofabarmagnet.Thenorthpoleofacompassneedle,usedfornavigation,gen-6.34kerallypointstowardthegeographicnorthpole.WhichmagneticpoleoftheEarthis47.5kthecompassneedlepointingtoward?7.87kthesouthmagneticpoleofEarth2.AmagnetisusedtocollectsomespilledRpaperclips.Whatisthemagneticpoleat1�29.4k�theendofthepaperclipthatisindicatedR23�6.34k��7.87k�inthefigure?�14.21k�RN45�25.5k��47.5k��73.0k�11111S��������������RRR14.21k�73.0k�p2345Rp�11.9k�R�R1�Rp�29.4k��11.9k��41.3k�northCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3.Jingdanturnedascrewdriverintoamagnetbyrubbingitwithastrongbarmagnettopickupascrewthathasfallenintoaninaccessiblespot.Howcouldhedemagnetizehisscrewdriverafterpickingupthescrew?Hecoulddropit,heatit,hititwithahammer,orsomehowotherwisejigglethemagneticdomainsintorandomness.4.Along,straight,current-carryingwirecarriesacurrentfromwesttoeast.Acompassisheldabovethewire.a.Whichdirectiondoesthenorthpoleofthecompasspoint?southb.Whenthecompassismovedunderneaththewire,inwhichdirectiondoesthenorthpolepoint?north662SolutionsManualPhysics:PrinciplesandProblems
664Chapter24continued5.Considerthesketchoftheelectromagnetin7.Howlongisawireina0.86-Tfieldthatthefigurebelow.Whichcomponentscouldcarriesacurrentof1.4Aandexperiencesyouchangetoincreaseordecreasetheaforceof13N?strengthoftheelectromagnet?ExplainyourF�ILBanswer.F13NL�������11mIB(1.4A)(0.86T)8.A6.0-Tmagneticfieldbarelypreventsa0.32-mlengthofcopperwirewithacurrentof1.8Afromdroppingtotheground.Whatisthemassofthewire?F�ILB�mgILB(1.8A)(0.32m)(6.0T)Toincreasethestrengthofthemagnet,m��g������20.35kg9.80m/sthevoltageofthepowersourcecouldbeincreased,thenumberofthewraps9.Howmuchcurrentwillbeneededtocouldbeincreased,orferromagneticproduceaforceof1.1Nona21-cm-longcorescouldbeadded.pieceofwireatrightanglestoa0.56-Tfield?Todecreasethestrengthofthemagnet,F1.1NI�������9.4AthevoltageofthepowersourcecouldLB(0.21m)(0.56T)bedecreased,fewerwrapscouldbeused,orhollowornonmagneticcores10.Alphaparticles(particlescontainingtwocouldbeused.protons,twoneutrons,butnoelectrons)aretravelingatrightanglestoa47-�Tfield6.Sketchagraphshowingtherelationshipwithaspeedof36cm/s.Whatistheforcebetweenthemagneticfieldaroundaoneachparticle?straight,current-carryingwire,andtheF�qvBdistancefromthewire.�(3.20�10�19C)(0.36m/s)(4.7�10�5T)�5.4�10�24N11.Aforceof7.1�10�12NisexertedonsomeAl3�ions(anatommissingthreeelectrons)thataretravelingat430km/sperpendiculartoamagneticfield.Whatisthemagneticfield?F7.1�10�12NB��������qv(4.80�10�19C)(4.3�105m/s)Magneticfieldstrength�34TDistancefromwire12.ElectronstravelingatrightanglestoamagneticfieldexperienceaforceofThisisagraphofy�1/x.Theunits/num-8.3�10�13Nwhentheyareinamagneticbersdonotmatter.They-axisshouldbeCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.fieldof6.2�10�1T.Howfastarethelabeledmagneticfieldstrengthandtheelectronsmoving?x-axisdistancefromwire.F8.3�10�13Nv��������qB(1.60�10�19C)(6.2�10�1T)�8.4�106m/sPhysics:PrinciplesandProblemsSolutionsManual663
665b.Whatisthepeakvoltageofthegenerator?Chapter25VeffV�page885max��92V�2�1.A72-cmwireismovedatanangleof72°throughamagneticfieldof1.7�10�2T5.WhatistheRMSvoltageofahouseholdandexperiencesanEMFof1.2mV.Howoutletifthepeakvoltageis125V?fastisthewiremoving?Veff��2�Vmax�(�2�)(165V)�117VEMFv���6.Anoutlethasapeakvoltageof170V.LBsin�1.2�10�3Va.Whatistheeffectivevoltage?�����(0.72m)(1.7�10�2T)(sin72°)Veff��2�Vmax�0.10m/s�(�2�)(170V)�120V2.A14.2-mwiremoves3.12m/sperpendicularb.Whateffectivecurrentisdeliveredtoantoa4.21-Tfield.11-toaster?a.WhatEMFisinducedinthewire?V120VI�������11AEMF�BLvsin�R11�(4.21T)(14.2m)(3.12m/s)7.Astep-uptransformerhasaprimarycoil(sin90.0°)consistingof152turnsandasecondarycoilwith3040turns.Theprimarycoilreceivesa�187Vpeakvoltageof98V.b.Assumethattheresistanceinthewireisa.Whatistheeffectivevoltageinthe0.89.Whatistheamountofcurrentprimarycoil?inthewire?I�V���187�V�2.1�102AVeff��2�Vmax�(�2�)(98V)�69V�R0.89�b.WhatistheeffectivevoltageintheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3.A3.1-mlengthofstraightwirehasasecondarycoil?resistanceof3.1.Thewiremovesatn2304026cm/satanangleof29°throughaV2��n�V1���15�2�(69V)�1.4kV1magneticfieldof4.1T.Whatistheinducedcurrentinthewire?8.Astep-downtransformerhas9000turnsEMF�BLvsin�ontheprimarycoiland150turnsonthesecondarycoil.TheEMFintheprimary�(4.1T)(3.1m)(0.26m/s2)(sin29°)coilis16V.Whatisthevoltagebeing�1.6Vappliedtothesecondarycoil?EMF1.6Vn1150I��R���3.1���0.52AV1��n�V2���90�00�(16V)�0.27V24.Ageneratordeliversaneffectivecurrent9.Atransformerhas124turnsontheof75.2Atoawirethathasaresistanceprimarycoiland18,600turnsontheof0.86.secondarycoil.a.Whatistheeffectivevoltage?a.Isthisastep-downorastep-uptransformer?Veff�IeffR�(75.2)(0.86)�65Vstep-up664SolutionsManualPhysics:PrinciplesandProblems
666Chapter25continuedb.IftheeffectivevoltageinthesecondaryChapter26coilis3.2kV,whatisthepeakvoltagebeingdeliveredtotheprimarycoil?pages885–886n1.Astreamofsinglyionized(1�)fluorineV��1V1,eff�n2,effatomspassesundeflectedthroughamag-2neticfieldof2.5�10�3Tthatisbalanced��12�4(3.2kV)�21V3V/m.The��byanelectricfieldof3.5�1018,600massofthefluorineatomsis19timesthatV1,max��2�V1,eff�(�2�)(21V)ofaproton.1a.Whatisthespeedofthefluorineions?�3.0�10Theelectricforceandmagneticforcesbalanceeachother.Bqv�EqEv���B3.5�103V/m���2.5�10�3T�1.4�106m/sb.Iftheelectricfieldisswitchedoff,whatistheradiusofthecircularpathfollowedbytheions?Themagneticforceactsasacen-tripetalforce.mv2Bqv��rmvr���Bq(19)(1.67�10�27kg)(1.4�106m/s)�����(1.60�10�19C)(2.5�10�3T)�110m2.AnelectronmovesperpendiculartoEarth’smagneticfieldwithaspeedof1.78�106m/s.IfthestrengthofEarth’smagneticfieldisabout5.00�10�5T,whatistheradiusoftheelectron’scircularpath?mv2Bqv��rmvr���Bq(9.11�10�31kg)(1.78�106m/s)�����(5.00�10�5T)(1.60�10�19C)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�0.203mPhysics:PrinciplesandProblemsSolutionsManual665
667Chapter26continued3.Aprotonwithavelocityof3.98�104m/sperpendiculartothedirectionofamagneticfieldfollowsacircularpathwithadiameterof4.12cm.Ifthemassofaprotonis1.67�10�27kg,whatisthestrengthofthemagneticfield?mv2Bqv��rmvB���rq(1.67�10�27kg)(3.98�104m/s)�����(2.06�10�2m)(1.60�10�19C)�2.02�10�2T4.Abeamofdoublyionized(2�)calciumatomsisanalyzedbyamassspectrome-ter.IfB�4.5�10�3T,r�0.125m,andthemassofthecalciumionsis6.68�10�26kg,whatisthevoltageofthemassspectrometer?q2V����mB2r2calciumqB2r2V��2m(3.20�10�19C)(4.5�10�3T)2(0.125m)2������(2)(6.68�10�26kg)�0.76V5.Thespeedoflightincrownglassis1.97�108m/s.Whatisthedielectricconstantofcrownglass?c�v��K�c2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.K����v3.00�108m/s2�����1.97�108m/s�2.326.Thedielectricconstantofdiamondis6.00.Whatisthespeedoflightindia-mond?cv���K�3.00�108m/s����6.00��1.22�108m/s666SolutionsManualPhysics:PrinciplesandProblems
668Chapter26continued7.Bycurvingdifferentisotopesthroughpathswithdifferentradii,amassspectrom-etercanbeusedtopurifyasampleofmixeduranium-235anduranium-238iso-topes.AssumethatB�5.00�10�3T,V�55.0V,andthateachuraniumisotopehasa5�ionizationstate.Uranium-235hasamassthatis235timesthatofapro-ton,whileuranium-238hasamassthatis238timesthatofaproton.Bywhatdis-tancewillthetwoisotopesbeseparatedbythemassspectrometer?R1�Uranium-235R2�Uranium-238R2R1Uraniumionbeamq2V����mB2r22Vmr�U-235���qB2(2)(55.0V)(235)(1.67�10�27kg)����������(5)(1.60�10�19kg)(5.00�10�3T)2�1.47m2Vmr�U-238���qB2(2)(55.0V)(238)(1.67�10�27kg)����������(5)(1.60�10�19kg)(5.00�10�3T)2�1.48mSeparation�rU-238�rU-235�1.48m�1.47m�0.01m8.AmassspectrometeroftenisusedincarbondatingtodeterminetheratioofC-14isotopestoC-12isotopesinabiologicalsample.Thisratiothenisusedtoestimatehowlongagotheonce-livingorganismdied.Becauseamassspectrometerissensi-tivetothecharge-to-massratio,itispossibleforacontaminantparticletoalterthevaluemeasuredfortheC-14/C-12ratio,andthus,yielderroneousresults.Whenion-ized,C-14formsanionwitha�4charge,andthemassofC-14is14timesthatofaproton.Consideracontaminantlithiumparticle.Ifthemostcommonlithiumiso-topehasamassthatisseventimesthatofaproton,whatmustbethechargeoftheCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.lithiumionneededtocontaminateacarbon-14experiment?qqC2VLi�������mB2r2mCLimLiq��Li�qCmCPhysics:PrinciplesandProblemsSolutionsManual667
669Chapter26continued7mp�(�4)����14mp��29.Whatisthewavelengthofaradiowavewithafrequencyof90.7MHz?c����f3.00�108m/s���90.7�106Hz�3.31m10.Whatisthefrequencyofamicrowavewithawavelengthof3.27mm?c����fcf����3.00�108m/s���3.27�10�3m�9.17�1010Hz11.WhatisthefrequencyofanXraywithawavelengthof1.00�10�10m?c����fcf����Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.3.00�108m/s���1.00�10�10m�3.00�1018Hz12.Inrecentyears,physicistshaveslowedthespeedoflightpassingthroughamaterialtoabout1.20mm/s.Whatisthedielectricconstantofthismaterial?cv���K�c2K����v3.00�108m/s2�����1.20�10�3m/s�6.25�1022668SolutionsManualPhysics:PrinciplesandProblems
670Chapter27pages886–8871.Ifthemaximumkineticenergyofemittedphotoelectronsis1.4�10�18J,whatisthestoppingpotentialofacertainphotocell?KE��qV0�KEV�0�q�1.4�10�18J����1.60�10�19C�8.8V2.Thestoppingpotentialofaphotocellis2.3V.Whatistheinitialvelocityofanemittedphotoelectronthatisbroughttoastopbythephotocell?12KE��qV��mv0�2�2qV�0v���m(�2)(�1.60�10�19C)(2.3V)��������9.11�10�31kg�9.0�105m/s3.Ifaphotoelectrontravelingat8.7�105m/sisstoppedbyaphotocell,whatisthephotocell’sstoppingpotential?12KE��qV��mv0�2�mv2V�0�2q�(9.11�10�31kg)(8.7�105m/s)2�����(2)(�1.60�10�19C)�2.2V4.Lightwithafrequencyof7.5�1014Hzisabletoejectelectronsfromthemetalsurfaceofaphotocellthathasathresholdfrequencyof5.2�1014Hz.Whatstoppingpotentialisneededtostoptheemittedphotoelectrons?KE�hf�hf0�h(f�f0)andKE��qV0Thus,�KE�h(f�f�(6.626�10�34J/Hz)(7.5�1014Hz�5.2�1014Hz)V�����0)�������0�qq�1.60�10�19C�0.95VCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual669
671Chapter27continued5.Ametalhasaworkfunctionof4.80eV.Willultravioletradiationwithawave-lengthof385nmbeabletoejectaphotoelectronfromthemetal?Firstcalculatetheenergyofthephoton.1240eV�nmE����1240eV�nm���385nm�3.22eVToejectaphotoelectronfromthemetal,theenergyoftheincidentradiationmustbegreaterthantheworkfunctionofthemetal.Becausetheenergyoftheincidentradiation,3.22eV,islessthantheworkfunction,4.80eV,aphotoelectronwillnotbeejected.6.WhenametalisilluminatedwithradiationCathodeAnodewithawavelengthof152nm,photoelectronsareejectedwithavelocityof7.9�105m/s.Whatistheworkfunction,ineV,ofthemetal?v�7.9�105m/sFirstcalculatetheenergyofthephotoninjoules.��152nmhcE����(6.626�10�34J/Hz)(2.998�108m/s)�������7��Incident1.52�10mradiation�1.31�10�18JNext,calculatethekineticenergy.12KE���mv2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.���1��(9.11�10�31kg)(7.9�105m/s)22�2.8�10�19JKE�E�WW�E�KE�1.31�10�18J�2.8�10�19J�1.0�10�18J�(1.0�10�18J)����1eV1.60�10�19J�6.2eV670SolutionsManualPhysics:PrinciplesandProblems
672Chapter27continued7.ThedeBrogliewavelengthforanelectrontravelingat9.6�105m/sis7.6�10�10m.Whatisthemassoftheelectron?h����mvhm����v6.626�10�34J/Hz�����(7.6�10�10m)(9.6�105m/s)�9.1�10�31kg8.WhatisthedeBrogliewavelengthofa68-kgmanmovingwithakineticenergyof8.5J?12KE���mv22KEv����mThedeBrogliewavelengthisthen,hhm���������mvm2KE1���h(2mKE)21�(6.626�10�34J/Hz)((2)(68kg)(8.5J))��2�1.9�10�35m9.AnelectronhasadeBrogliewavelengthof5.2�10�10m.Whatpotentialdifferenceisresponsibleforthiswavelength?h����mvhv����mand12KE�–qV��mv0�2�mv2V��0�2q�mh2��2q�2m2�h2��2q�2m�(6.626�10�34J/Hz)2�������(2)(�1.60�10�19C)(5.2�10�10m)2(9.11�10�31kg)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.�5.6VPhysics:PrinciplesandProblemsSolutionsManual671
673Chapter28page8871.AnelectroninahydrogenatommakesatransitionfromE3toE1.Howmuchenergydoestheatomlose?1E�n��13.6eV�n2�E�E1�E3�13.6�13.6����12��32��12.1eV2.Anelectroninthehydrogenatomloses3.02eVasitfallstoenergylevelE2.Fromwhichenergyleveldidtheatomfall?�E�Ef�Ei11�3.02eV��13.6����n2n2�yx13.6eV�3.02eV�3.40eV��n2xnx�63.Whichenergylevelinahydrogenatomhasaradiusof7.63�10�9m?h2n2r���4�2Kmq24�2Kmq2rn�����h2Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.4�2(9.0�109N�m2/C2)(9.11�10�31kg)(1.60�10�19C)2(7.63�10�9m)����������������(6.626�10�34J�s)2�12Alternatively,r�r2wherer0m0istheBohrradiusinhydrogen,530mm.r7.63�10�9mThus,m����������5.30�10�11m��144��12r04.WhenanelectronfallsfromE4toE1,whatisthefrequencyoftheemittedphoton?�E�E1�E4�(�2.17�10�18J)���1�18J)�112��(�2.17�10���42�2.04�10�18JE�hfEf���h2.04�10�18J����6.626�10�34J�s�3.08�1015Hz672SolutionsManualPhysics:PrinciplesandProblems
674Chapter28continued5.IfanelectronmovesfromE3toE5,whatisthewavelengthofthephotonabsorbedbytheatom?�E�E5�E3�(�2.17�10�18J)���1��(�2.17�10�18J)����15232�1.54�10�19Jhc�E�hf���dhcd����E(6.626�10�34J�s)(3.00�108m/s)������1.54�10�19J�1.29�10�6m6.Ifahydrogenatominitsgroundstateabsorbsaphotonwithawavelengthof93nm,itjumpstoanexcitedstate.Whatisthevalueoftheenergyinthatexcitedstate?hcE�hf����(6.626�10�34J�s)(3.00�108m/s)������9.3�10�8m�2.14�10�18J�(2.14�10�18J)����1eV1.60�10�19J�13.3eVabsorbedEf�Ei��E��13.6eV�13.3eV��0.27eVCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Physics:PrinciplesandProblemsSolutionsManual673
675Chapter29pages887–8881.Indiumhas3freeelectronsperatom.UseAppendixDanddeterminethenum-beroffreeelectronsin1.0kgofindium.freee��/atom)(N11000g��(freee���kgA)�M��1kg�Substitute:freee�/atom�3freee�/1atom,N23atoms/mol,M�114.82g/molA�6.02�10freee�3freee�6.02�1023atoms1mol1000g�kg�����1atom����1mol���114.82g����1kg�1.57�1025freee�/kgforindium2.Cadmiumhas2freeelectronsperatom.UseAppendixDanddeterminethenumberoffreeelectronsin1.0dm3ofCd.freee��/atom)(N11000cm3��(freee��(�)��dm3A)�M���1dm3Substitute:freee�/atom�2freee�/1atom,N23atoms/mol,M�112.41g/mol,A�6.02�10��8.65g/cm3freee�2freee�6.02�1023atoms1mol8.65g1000cm3�dm3�����1atom����1mol�����112.41g���1cm3����1dm3�9.26�1025freee�/dm3incadmium3.Copperhas1freeelectronperatom.Whatlengthof1.00-mmdiametercopperCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.wirecontains7.81�1024freeelectrons?UseAppendixDforphysicalconstants.1�)�atoms11Lwire�����r2(numberoffreee��freee���N�(M)����ASubstitute:N23atoms/mol,A�6.02�10M�63.546g/mol,��8.92g/cm3,numberoffreee��7.81�1024freee�,rwire�1.00mm/2�0.50mm�0.050cmL1(7.81�1024freee�)��1atomwire���2��1freee���0.100cm�����21mol63.546g1cm3��������6.022�1023atoms�1mol��8.92g��1.18�104cm�118m674SolutionsManualPhysics:PrinciplesandProblems
676Chapter29continued4.At400.0K,germaniumhas1.13�1015freeelectrons/cm3.HowmanyfreeelectronsperGeatomarethereatthistemperature?freee�11������(M)����(freee�cm3forGe)atomN�ASubstitute:N23atoms/mol,A�6.02�10M�72.63g/mol,��5.23g/cm3,freee�/cm3forGe�1.13�1015freee�/cm3freee�1mol72.63g1cm31.13�1015freee�����������atom��6.02�1023atoms�1mol��5.23g���cm3freee�/atomofGeat400.0K�2.61�10�85.At400.0K,siliconhas4.54�1012freeelectrons/cm3.HowmanyfreeelectronsperSiatomarethereatthistemperature?freee�11������(M)����(4.54�1012freee�/cm3forSi)atomN�ASubstitute:N23atoms/mol,M�28.09g/mol,��2.33g/cm3,A�6.02�10freee�/cm3forSi�4.54�1012freee�/cm3at400.0Kfreee�1mol28.09g1cm34.54�1012freee�����������atom��6.02�1023atoms�1mol��2.33g���cm3freee�/atomofSiat400.0K�9.09�10�116.At200.0K,siliconhas3.79�10�18freeelectronsperatom.Howmanyfreeelectrons/cm3arethereinsiliconatthistemperature?freee�freee�1���(N��(�)cm3��atomA)�M�Substitute:freee�/atom�3.79�10�18freee�/1atom,N23atoms/mol,M�28.09g/mol,��2.33g/cm3A�6.02�10freee�3.79�10�18e�6.02�1023atoms1mol2.33g�cm3�����1atom�����1mol�28.09g����1cm3��1.89�105freee�/cm3insiliconat200K7.Siliconhas1.45�1010freeelectrons/cm3atroomtemperature.Ifyouwantedtohave3�106asmanyelectronsfromarsenicdopingasthermalfreeelectronsfromsiliconatroomtemperature,howmanyarsenicatomsshouldtherebeforeachsiliconatom?Eacharsenicatomprovides1freeelectron.UseAppendixDforphysicalconstants.AsatomsnumberAsatomsnumberofAse����������������SiatomsAsethermaleCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.numberofthermale�11���(M)����cm3��N���ASubstitute:M�28.09g/mol,N23atoms/mol,��2.33g/cm3,A�6.02�101Asatom�1Ase�,3�106Ase�/thermale�,numberofthermale�/cm3�1.45�1010e�/cm3Physics:PrinciplesandProblemsSolutionsManual675
677Chapter29continuedAsatoms1Asatoms3�106Ase�1.45�1010thermale�28.09g��Siatoms�����1Ase�����thermale�����cm3���m�ol�molcm3������6.02�1023Siatoms�2.33g��8.71�10�78.At200.0K,germaniumhas1.16�1010thermallyliberatedchargecarriers/cm3.Ifitisdopedwith1Asatomto525,000Geatoms,whatistheratioofdopedcarrierstothermalcarriersatthistemperature?SeeAppendixDforphysicalconstants.dopedcarriersdopedcarriers11������(N���thermalcarriers��5.25�105atomsA)��M(�)��thermalcarriersSubstitute:M�72.6g/mol,N23atoms/mol,��5.23g/cm3A�6.02�10thermalcarriers�1.16�1010thermalcarriers/cm3dopedcarriers1dopedcarrier6.02�1023atomsmol5.23g�����������thermalcarriers�5.25�105atoms��mol���72.6g��cm3cm3������1.16�1010thermalcarriers�7.12�1069.At200.0K,siliconhas1.89�105thermallyliberatedchargecarriers/cm3.Ifitisdopedwith1Asatomto3.75millionSiatoms,whatistheratioofdopedcarri-erstothermalcarriersatthistemperature?SeeAppendixDforphysicalconstants.dopedcarriersdopedcarriers11������(N���thermalcarriers��3.75�106atomsA)��M(�)��thermalcarriersCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Substitute:M�28.09g/mol,N23atoms/mol,��2.33g/cm3A�6.02�10thermalcarriers�1.89�105thermalcarriers/cm3dopedcarriers1dopedcarrier6.02�1023atomsmol2.33g�����������thermalcarriers��3.75�106atoms��mol�28.09g��cm3�cm3������1.89�105thermalcarriers�7.05�101010.Thediodeshownbelowhasavoltagedrop,Vd,Rof0.45VwhenI�11mA.Ifa680-�resistor,R,isconnectedinseries,whatpowersupplyvoltage,IVbisneeded?Vb�IR�Vd�(0.011A)(680�)�0.45VVb�7.9VDiodeVd676SolutionsManualPhysics:PrinciplesandProblems
678Chapter29continued11.AdiodeinacircuitsimilartotheoneinChapter30Figure29-26hasavoltagedrop,Vd,of0.95VwhenI�18mA.Ifa390-�resistor,pages888–889R,isconnectedinseries,whatpowersupply1.Carbon-14,or14C,isanisotopeofthevoltage,Vcommon12bisneeded?6C,andisusedindatingancientVartifacts.Whatisthecompositionofitsb�IR�Vdnucleus?�(0.018A)(390�)�0.95Vsixprotons(equaltoZ)andeight�8.0Vneutrons(equaltoA�Z)12.Whatpowersupplyvoltagewouldbeneeded2.Anisotopeofiodine(Z�53)isusedtotoproduceacurrentof27mAinthecircuittreatthyroidconditions.Itsmassnumberisinproblem10?Assumethediodevoltageis131.Howmanyneutronsareinitsnucleus?uncharged.131�53�78neutronsVb�IR�Vd3.Theonlynonradioactiveisotopeoffluorine�(0.027A)(680�)�0.45Vhasnineprotonsandtenneutrons.�19Va.Whatisitsmassnumber?massnumber(A)�19b.Theatomicmassunit,u,isequalto1.66�10�27kg.Whatisfluorine-19’sapproximatemassinkilograms?(19nucleons)(1.66�10�27kg/nucleon)�3.15�10–26kgc.Writethefullsymbolofthisatom.199F4.Themagnesiumisotope2512Mghasamassof24.985840u.a.Calculateitsmassdefect.massdefect�(isotopemass)�(massofprotonsandelectrons)�(massofneutrons)�24.985840u�(12)(1.007825u)�(13)(1.008665u)��0.220705ub.CalculateitsbindingenergyinMeV.bindingenergy�(massdefect)(bindingenergyof1u)�(�0.220705u)(931.49MeV/u)Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.��205.58MeVPhysics:PrinciplesandProblemsSolutionsManual677
679Chapter30continued5.Theisotope10b.Identifytheparticlethatisejected.5Bhasamassof10.012939u.a.Calculatethemassdefect.an�particlemassdefect�(isotopemass)�2228.Theradioisotope84Poundergoesalpha(massofprotonsandelectrons)�decaytoformanisotopeoflead(leadhas(massofneutrons)atomicnumber82).Determinewhatthemassnumberofthatisotopemustbeby�10.012939u�(5)(1.007825u)�writinganuclearequation.(5)(1.008665u)222A4��0.069511u84Po→ZPb�2Heb.CalculateitsbindingenergyinMeV.whereZ�84�2�82bindingenergy�(massdefect)A�222�4�218(bindingenergyof1u)Thustheequationis222218484Po→82Pb�2He�(�0.069511u)(931.49MeV/u)Themassnumberis218.��64.749MeV9.Thegraphbelowshowsasequenceofalphac.Calculateitsbindingenergypernucleon.andbetadecays,labeled1,2,3,and4.bindingenergypernucleonisConsultTable30-1asneeded.�64.744MeV����6.4749MeV/nucleonA10nucleons2186.Themoststableisotopeofallis5626Fe.Itsbindingenergypernucleonis1216�8.75MeV/nucleon.a.Whatisthebindingenergyofthis3214isotope?2(56nucleons)(–8.75MeV/nucleon)�Massnumber2124–4.90�102MeVCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.b.Whatisthemassdefectofthisisotope?210bindingenergymassdefect����bindingenergyof1u808284Z�4.90�102MeVAtomicnumber���931.49MeV/ua.Whichrepresentalphadecays,and��0.526uwhichrepresentbetadecays?7.Theisotope239alphadecays:1and4,inwhich94Pucanbetransmutedtoanisotopeofuranium,235massnumberdecreasesby4and92U.atomicnumberby2;betadecays:2a.Writethenuclearequationforthisand3,inwhichatomicnumbertransmutation.increasesby1andmassnumber239Pu→235A9492U�ZXstaysthesamewhereZ�94�92�2b.WhatistheoverallchangeinmassintheA�239�235�4sequence?Inthenumberofneutrons?ForZ�2,theelementmustbeOverallchangeinmassis218u�helium.Thustheequationis210u�8ulower.Overallchangein2392354Zis84–82�2lower.Thus,overall94Pu→92U�2Hechangeinthenumberofneutronsis6lower(8nucleonsless,2protonsless,so6neutronsless).678SolutionsManualPhysics:PrinciplesandProblems
680Chapter30continued10.UseAppendixDtocompletethetwo13.Iodine-131hasahalf-lifeof8.0days.Ifnuclearequations.Includecorrectthereare60.0mgofthisisotopeattimesubscriptsandsuperscriptsforeachzero,howmuchremains24dayslater?oftheparticles.24days����3.0half-livesa.328.0days/half-life15P®?���antineutrino1t32A0e�0remaining�original���15P→ZX��10��2whereZ�15�(�1)�0�1613.0�(60.0mg)���2A�32�0�0�32�7.5mgForZ�16,theelementmustbesulfur.Thus,theequationis14.RefertoTable30-2.Givenasampleof32320e�015P→16S��10��cobalt-60,b.235a.howlongatimeisneededforittogo92U®?�throughfourhalf-lives?235A492U→ZX�2He(4)(30years)�120yearswhereZ�92�2�90b.whatfractionremainsattheendofthatA�235�4�231time?1tForZ�90,theelementmustberemaining�original���2thorium.Thus,theequationis23523141492U→90Th�2He�original���211.Writethecompletenuclearequationforthe����1original3416betadecayof16S.34A0e�015.Thegraphshowstheactivityofacertain16S→ZX��10��radioisotopeovertime.Deduceitshalf-lifewhereZ�16�(�1)�0�17fromthisdata.A�34�0�0�34ForZ�17,theelementmustbe48chlorine.Thus,theequationis34340e�016S→17Cl��10��(Bq)3651012.Apositronisidenticaltoabetaparticle,�24exceptthatitschargeis�1insteadof�1.3719KundergoesspontaneouspositronActivitydecaytoformanisotopeofargon.Identify12theisotopeofargonbywritinganuclearequation.03691237A0e�019K→ZAr��10��Time(h)whereZ�19�1�0�18Every3.0htheactivityishalfofthepre-A�37�0�0�37viousactivity,sothehalf-lifeis3.0h.Copyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.Thustheequationis37370e�019K→18Ar��10��Theisotopeisargon�37.Physics:PrinciplesandProblemsSolutionsManual679
681Chapter30continued16.Themassofaprotonandofanantiproton18.When1mol(235g)ofuranium-235is1.00728u.Recallthattheconversionofundergoesfission,about2.0�1010kJofexactly1uintoenergyyields931.5MeV.energyarereleased.When4.0gofhydro-a.Calculatethemassusedupwhenagenundergoesfusion,about2.0�109kJareprotonandanantiprotonannihilatereleased.oneanother.a.Foreach,calculatetheenergyyieldper(2)(1.00728u)�2.01456ugramoffuel.2.0�109kJ8b.Calculatetheenergyreleasedhere.���5.0�104.0g(2.01456u)(931.5MeV/u)�1876.5MeVkJ/gforfusionofhydrogen;17.Onesourceofastar’senergyisthefusionof2.0�1010kJ7���8.5�10235gtwodeuteronstoformanalphaparticleplusagammaray.kJ/gforfissionofuraniumb.WhichprocessproducesmoreenergyParticleMassinupergramoffuel?2H2.01361Fusionreleasesaboutsixtimesas4He4.00262muchenergypergramoffuelas0�0.00000fission.a.Writethenuclearequationforthisfusion.22401H�1H→2He�0b.Calculatethemass“lost”inthisprocess.massbefore�massafter�2(2.0136u)�4.0026u�0.0246uCopyright©Glencoe/McGraw-Hill,adivisionofTheMcGraw-HillCompanies,Inc.c.CalculatetheenergyreleasedinMeV.(0.0246u)(931.49MeV/u)�22.9MeV680SolutionsManualPhysics:PrinciplesandProblems
