(Pre- and) Post Tests and Surveys - physics.rutgers.educizewski/227_s2018/L24-CH32b-post.pdf ·...
32
(Pre- and) Post Tests and Surveys All engineering students are being tested in their core courses this academic year at the beginning of the semester and again at the end of the semester. These data will be used to improve your learning experiences. • Your responses to these tests & surveys will have no bearing on your course grade. • I will not see your scores. • I will only track whether or not you took the tests and surveys. • There are four components to the pre and post test requirements: • Two in-class exams; Two on-line surveys • An exam and a survey both at the beginning and at the end of the semester. • If you participate in all 4 components, you will get 100% on 2% of your grade • If you miss any of the 4 components, you will get a zero for 2% of your grade. • Second in-class exam Thursday, April 26 in lecture. Take survey TODAY and save confirmation page. Deadline Monday April 30 11:59 pm. https://rutgers.ca1.qualtrics.com/jfe/form/SV_2lVQrms4jn96hJX • Take the exams and surveys seriously! Answer all parts to best of your abilities. • If you do not take the exams and surveys seriously, you will get a zero. • If you take the exams or surveys for someone else OR you ask someone to take the exams for you, you will not only get a zero but may be separated from the university because you have violated academic integrity. 1
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Transcript of (Pre- and) Post Tests and Surveys - physics.rutgers.educizewski/227_s2018/L24-CH32b-post.pdf ·...
(Pre-and)PostTestsandSurveysAllengineeringstudentsarebeingtestedintheircorecoursesthisacademicyearatthebeginningofthesemesterandagainattheendofthesemester.Thesedatawillbeusedtoimproveyourlearningexperiences.• Yourresponsestothesetests&surveyswillhavenobearingonyourcoursegrade.• Iwillnotseeyourscores.• Iwillonlytrackwhetherornotyoutookthetestsandsurveys.
• Therearefourcomponentstothepreandposttestrequirements:• Twoin-classexams;Twoon-linesurveys• Anexamandasurveybothatthebeginningandattheendofthesemester.• Ifyouparticipateinall4components,youwillget100%on2%ofyourgrade• Ifyoumissanyofthe4components,youwillgetazerofor2%ofyourgrade.• Secondin-classexamThursday,April26inlecture.
TakesurveyTODAYandsaveconfirmationpage.DeadlineMondayApril3011:59pm.https://rutgers.ca1.qualtrics.com/jfe/form/SV_2lVQrms4jn96hJX
• Taketheexamsandsurveysseriously!Answerallpartstobestofyourabilities.• Ifyoudonottaketheexamsandsurveysseriously,youwillgetazero.• IfyoutaketheexamsorsurveysforsomeoneelseORyouasksomeonetotakethe
examsforyou,youwillnotonlygetazerobutmaybeseparatedfromtheuniversitybecauseyouhaveviolatedacademicintegrity. 1
Summerstudyopportunity:PlasmaphysicsUndergraduatePlasmaPhysicsWorkshop
July18through20,2018atPrincetonPlasmaPhysicsLabThisworkshoptargetsfirstandsecond-yearundergradsandintroducesthemtoplasmaphysicsfromanexperimentalandatheoreticalperspective.Theobjectiveisforparticipantstogainanintroductoryunderstandingofthefieldofplasmaphysicsandopportunitieswithin.Alltravel,boardingandmealswillbecoveredbyPPPL.Underrepresentedstudentsareespeciallyencouragedtoapply.
https://www.pppl.gov/education/science-education/programs/workshop-plasma-physics-undergraduates 2
AnnouncementsThisweek: courseevalhttps://sakai.rutgers.edu/portal/site/sirs• Requiredposttest–ThursdayApril26inlecture
• Ifmisslecture,limitedopportunityformakeup;elsezerofor2%ofgrade
• Homework10dueThursdayApril26:Chapter31+32• RecitationonFridayApril27:Chapter32.• QuizonFridayApril27:Homework10,Lectures22+23+24
Finalexam:Wednesday,May9,20184:00to7:00PMinPhysicsLectureHall.
• 30multiplechoicequestions,≈15fromChapters30-32,≈15cumulativeChapters21-29
• ReviewsessionTuesday,May84to6PM227SerinPhysics&Astro
Allexamsareclosed-book,nocalculatorsorotherelectronicdevicesallowed.
AnnouncementsFinalexam
• Wednesday,May9,2018inlecture:4:00–7:00pm• 30multiplechoicequestions.≈15fromChapters30-32,≈15fromChapters21-29
• ExamreviewTuesday,May8,4:00– 6:00pm227SerinPhysics&Astro
Allexamsareclosed-book,nocalculatorsorotherelectronicdevicesallowed.Allquestionswillbemultiplechoice.Forthefinalexam,youmaybringwithyouthree(3)"formulasheets",on8.5x11inchsheetsofpaper(OKtousebothsides)onwhichyoumayhandwriteanyformulaeordiagramsornotesorproblemsolutionsthatmightbehelpfultoyouduringtheexam.Informationonthesheetsmustbehandwritten,noattachmentsareallowed.Thenumericalvaluesofrelevantconstantswillbeprovidedtoyou.Youshouldbring#2pencilstotheexamsforthecomputerforms.
Typesofquestions:LikeI-clickers,simplenumbers,formulaeStudy:Homework,Iclickers,examplesintextbook,collaborative+pre-RECOldexams:http://www.physics.rutgers.edu/~cizewski/227_s2018/Physics-227-s2018-old-exams.htm
FreetutoringviaMSLC:https://rlc.rutgers.edu/services/peer-tutoring
Lecture24TuesdayApril24,2018
Chap32continued:ElectromagneticWavesEnergy,momentumRadiationpressureStandingwaves
5
ModelofE-M
6
http://www.surendranath.org/GPA/Waves/EMWave/EMWave.html
SummaryChapter32E-MwavesMaxwell’sequations=>electromagneticwaves• Travelingatspeedoflightinvacuum
• Transverse;directionofpropagation
• Sinusoidal
7
c = 1ε0µ0
= 3×108 m/s
!E ×!B
!E(x,t) �= y
∧
Emax cos(kx −ωt)!B(x,t) �= z
∧
Bmax cos(kx −ωt)
Emax = cBmax
• Wavemotionisfunctionofposition(x)andtime(t)
Wherev=phasevelocityofthewaveX
y
Z
SinusoidalWaves
8
MechanicalWaves-review
y(x,t)= Acos(kx −ωt)
k =2πλ
ω = vk
E-MWavespropagatingin+xdirection!E(x,t) �= y
∧
Emax cos(kx −ωt)!B(x,t) �= z
∧
Bmax cos(kx −ωt)
Emax = cBmax
IclickerquestionTheelectricpartofanelectromagneticwavemovinginthe+zdirectionisgivenby
WhichofthefollowingstatementsabouttheycomponentofthemagneticfieldpartisCORRECT?
9
Ex = Asin(kz −ωt), Ey = Ez = 0
(A) By ∝ cos(ky−ωt)
(B) By ∝ cos(kz −ωt)
(C) By ∝ sin(kz −ωt)
(D) By = 0
(E) By isgiven bysomeother expression.
IclickeranswerTheelectricpartofanelectromagneticwavemovinginthe+zdirectionisgivenby
WhichofthefollowingstatementsabouttheycomponentofthemagneticfieldpartisCORRECT?
10
Ex = Asin(kz −ωt), Ey = Ez = 0
(A) By ∝ cos(ky−ωt)
(B) By ∝ cos(kz −ωt)
(C) By ∝ sin(kz −ωt)
(D) By = 0
(E) By isgiven bysomeother expression.
SummaryChapter32E-MwavesMaxwell’sequations=>electromagneticwaves• Travelingatspeedoflightinvacuum
• Transverse;directionofpropagation
• Sinusoidal
Next:EnergyandmomentumofE-Mwaves
11
c = 1ε0µ0
= 3×108 m/s
!E ×!B
!E(x,t) �= y
∧
Emax cos(kx −ωt)!B(x,t) �= z
∧
Bmax cos(kx −ωt)
Emax = cBmax
EMEnergy(flow)inEMwaveEMwavescarryenergy,intheelectricandmagneticfields• Recallenergydensities
12
u = uE +uB =12ε0E
2 +1
2µ0
B2
B =Ec= ε0µ0E
EnergydensityofB-field=EnergydensityofE-fieldButE(position,time)=>u(position,time)
u =12ε0E
2 +1
2µ0
ε0µ0E( )2= ε0E
2 = u
c = 1ε0µ0
EMEnergy(flow)inEMwave• EnergyinvolumedV=areaxdistancetraveledintimedt
• Energyflowperunittimeperunitarea(invacuum)=S
• S“points”indirectionofenergyflow=directionofpropagationoftheEMwave
Ø ThePoyntingvector• Units:power/unitarea• BecauseE,B(position,time)=>S(position,time)
13
dU = udV = ε0E2(Acdt)
S =1AdUdt
= ε0cE2 = ε0cE(cB)=
EBµ0
!S =
1µ0
!E ×!B
c = 1ε0µ0
EMEnergyflow/intensityinEMwaveAssumesinusoidalwavetravelingin+xdirection
• Direction=+xdirection• Magnitude
• TimeaverageofS:• Timeaverageofcos=0• IntensityI=Sav
14
!S(x,t)=
1µ0
y∧
Emax cos(kx −ωt)× z∧
Bmax cos(kx −ωt)⎡⎣⎢
⎤⎦⎥
!E(x,t) �= y
∧
Emax cos(kx −ωt)!B(x,t) �= z
∧
Bmax cos(kx −ωt)
S =1µ0
EmaxBmax cos2(kx −ωt)=
1µ0
EmaxBmax 1+ cos2(kx −ωt)[ ]
I = Sav =EmaxBmax
µ0
=E2
max
2µ0c=12ε0cE
2max
!S =
1µ0
!E ×!B
c = 1ε0µ0
Imaginethatwhenyouswitchonyourlamp,youincreasetheintensityoflightshiningonyourtextbookbyafactorof16.Bywhatfactordoestheaverageelectricfieldstrengthinthislightincrease?
Iclickerquestion
15
A. Factorof256B. Factorof16C. Factorof4D. Factorof2E. Factorof1
I = Sav =EmaxBmax
µ0
=E2
max
2µ0c=12ε0cE
2max
Imaginethatwhenyouswitchonyourlamp,youincreasetheintensityoflightshiningonyourtextbookbyafactorof16.Bywhatfactordoestheaverageelectricfieldstrengthinthislightincrease?
Iclickeranswer
16
A. Factorof256B. Factorof16C. Factorof4D. Factorof2E. Factorof1
I = Sav =EmaxBmax
µ0
=E2
max
2µ0c=12ε0cE
2max
Imaginethatwhenyouswitchonyourlamp,youincreasetheintensityoflightshiningonyourtextbookbyafactorof16.Ifyourbookisr=1mfromyourlamp,howintenseisthelightsource?(i.e.,whatisthetotalenergyflow/unittimeoutofthelamp?)
Powerofthesource
17
I = Sav =E2
max
2µ0c
P =!Sav •d
!A"∫ = I(4πr2 )
I =P
4πr2
Radpressureexample
18
• Cometdusttails
http://hildaandtrojanasteroids.net/comettails.jpg
Electromagneticwavescarrymomentum• EMradiationismadeupof“particles”=photonsthatcarryenergyandmomentum• Momentumdensity:
• Averagerateofmomentumtransfer/area:wheredV=Acdt
Momentumflow&pressureinEMwave
19
p =energy
c
dpdt
1A=Savc=Ic
dpdV
=1cd(energy)
dV=ε0E
2
c=ε0EcB
c= ε0EB
µ0
µ0
=Sc2
dpdV
=Sc2
c = 1ε0µ0
!S =
1µ0
!E ×!B
E = cB
Electromagneticwavescarrymomentum• Averagerateofmomentumtransfer/area:
Pressure=force/unitarea=(dp/dt)/unitarea• AmountofpressuredependsuponwhetherEMwaveis
• Totallyabsorbed
• Totallyreflected(changeinmomentumdoubled)
Momentumflow&pressureinEMwave
20
dpdt
1A=Savc=Ic
prad =Savc=Ic
prad =2Savc
=2Ic
StandingEMwavesConsiderlinearlypolarizedEMwavetravelingin-xdirectiononaperfectconductor• Emustbezeroeverywhereonthey-z
conductingplane• ButincidentE≠0iny-zplane• NetEfield=0=incident+reflected
oscillatingE-field
21
Ey(x,t)�= Emax cos(kx +ωt)− cos(kx −ωt)[ ]
Bz(x,t)�= Bmax −cos(kx +ωt)− cos(kx −ωt)[ ]
cos(A±B)= cosAcosB ∓ sinAsinB
Ey(x,t)�= −2Emax sin kx sinωt
Bz(x,t)�= −2Bmax coskx cosωt
StandingEMwavesinacavity• Standingwaves
• Ehastobezeroatx=0andx=L• Definesnormalmodes
22
Ey(x,t)�= −2Emax sin kx sinωt
Bz(x,t)�= −2Bmax coskx cosωt
L
https://www.pitt.edu/~jdnorton/teaching/HPS_0410/chapters_2017_Jan_1/quantum_theory_origins/index.html
λn =2Ln
n = 1,2,3...
fn =cλn
= nc2L
StandingEMwaves• Standingwaves
• Atx=0,Ealwayszero• E=0wheresinkx=0Ø NodalplanesofE
• AntinodalplanesofE(whenE=max)= NodalplanesofBwhencoskx=0• NoteE(t)issinωtandB(t)iscosωt
Ø EandBfieldsareoutofphasewheninastandingwave23
Ey(x,t)�= −2Emax sin kx sinωt
Bz(x,t)�= −2Bmax coskx cosωt
x = 0,λ2, λ,
3λ2
...
kx = 0, π , 2π ...
x =λ4,3λ4,5λ4
...
kx =π2,3π2,5π2...
StandingEMwaves• Standingwaves
• Atx=0,Ealwayszero• E=0wheresinkx=0• NodalplanesofE
• AntinodalplanesofE(whenE=max)= NodalplanesofBwhencoskx=0• NoteE(t)issinωtandB(t)iscosωt
Ø EandBfieldsareoutofphasewheninastandingwave24
Ey(x,t)�= −2Emax sin kx sinωt
Bz(x,t)�= −2Bmax coskx cosωt
x = 0,λ2, λ,
3λ2
...
kx = 0, π , 2π ...
x =λ4,3λ4,5λ4
...
kx =π2,3π2,5π2...
Anti-node
Node
L =3λ2
• WhatisdistancebetweennodalplanesofE-field?
• NodalplanesofEfieldwhen
• Distancebetweennodalplanes=λ/2 = 5 m4=2.5 m
StandingwavenodalplanesforEandBfields
x = 0,λ2, λ,
3λ2
...
GivenstandingEMwavewithfrequencyf=30MHzWavelength λ = v
f=3×108 m/s30×106 /s
= 10 m
• NodalplanesofEfieldwhen
• Distancebetweennodalplanes=λ/2 = 5 m
• WhatisdistancebetweennodalplaneofE-fieldandnodalplaneofB-field?• NodalplanesofBfieldwhen(alsoanti-nodalplanesofEfield)
• DistancebetweennodalplanesofEandBfields=λ/4=2.5 m
StandingwavenodalplanesforEandBfields
x = 0,λ2, λ,
3λ2
...
GivenstandingEMwavewithfrequencyf=30MHzWavelength λ = v
f=3×108 m/s30×106 /s
= 10m
x =λ4,3λ4,5λ4...
IclickerquestionThedrawingshowsasinusoidalelectromagneticstandingwave.Whichofthefollowingstatementsabouttheaverage(averagedovereitherxort)PoyntingvectorinthiswaveisCORRECT?
27
A. TheaveragePoyntingvectorinthiswavepointsalongthex-axis.B. TheaveragePoyntingvectorinthiswavepointsalongthey-axis.C. TheaveragePoyntingvectorinthiswavepointsalongthez-axis.D. TheaveragePoyntingvectorinthiswaveiszero.
E. NoneoftheabovestatementsabouttheaveragePoyntingvectorinthiswaveiscorrect.
Sav =<1µ0
!E ×!B >sinacosa =
12sin2a
IclickeranswerThedrawingshowsasinusoidalelectromagneticstandingwave.Whichofthefollowingstatementsabouttheaverage(averagedovereitherxort)PoyntingvectorinthiswaveisCORRECT?
28
A. TheaveragePoyntingvectorinthiswavepointsalongthex-axis.B. TheaveragePoyntingvectorinthiswavepointsalongthey-axis.C. TheaveragePoyntingvectorinthiswavepointsalongthez-axis.D. TheaveragePoyntingvectorinthiswaveiszero.
E. NoneoftheabovestatementsabouttheaveragePoyntingvectorinthiswaveiscorrect.
Sav =<1µ0
!E ×!B >sinacosa =
12sin2a
IclickersolutionThedrawingshowsasinusoidalelectromagneticstandingwave.Whichofthefollowingstatementsabouttheaverage(averagedovereitherxort)PoyntingvectorinthiswaveisCORRECT?
29
Sav =<1µ0
!E ×!B >
Sav =<1µ0
!E ×!B >=<
1µ0
Emax sin kx sinωtBmax coskx cosωt >
=<1µ0
EmaxBmax sin kx coskx sinωt cosωt >
=<1µ0
EmaxBmax{12sin2kx
12sin2ωt}>= 0
sinacosa =12sin2a
SummaryChapter32• Maxwell’sequationsinvacuum,freespaceØ EMwaves
• Directionofpropagation
• Sinusoidal
• Power/unitarea=Poyntingvector
Ø IntensityofEMwave
• RadiationpressureofEMwave
• StandingEMwaves30
E = cB c = 1ε0µ0
= 3×108 m/s
!S =
1µ0
!E ×!B
!E ×!B
!E(x,t) �= y
∧
Emax cos(kx −ωt)!B(x,t) �= z
∧
Bmax cos(kx −ωt)
I = Sav =EmaxBmax
µ0
=12ε0cE
2max
prad (absorbed) =Savc=Ic
prad (reflected) =2Savc
=2Ic
SummaryChapter32(cont)StandingE-Mwaves• EandB90°outofphase
• NodeswhereE=0;antinodesB=max:
• AntinodeswhereE=max;nodesB=0:
• Standingwavesinacavity
31
Ey(x,t)�= −2Emax sin kx sinωt
Bz(x,t)�= −2Bmax coskx cosωt
kx =π2,3π2,5π2...
kx = 0, π , 2π ...
https://www.pitt.edu/~jdnorton/teaching/HPS_0410/chapters_2017_Jan_1/quantum_theory_origins/index.html
SeeyouonThursday
SummaryofthesemesterRequiredposttestThursdayApril26
FinalExamWednesday,May9
32
