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What is the frequency? f=c/w =3.00*108/4.10x1012 = 0.73 x1020 =7.3*1019 m Green light has a frequency of 6.01 x 1014 Hz. What is the wavelength? f=c/w =3.00*108/6.01x1014 =0.499*10-6 m = 4.99*10-7 m What is the wavelength (in meters) of the electromagnetic carrier wave transmitted by The Sports Fan radio station at a frequency of 640 kHz?(Hint: convert kHz into Hz by multiplying by 103.) f=6.4x10(3+2) = 6.4x105 w=3.00x108/6.4*105 0.47 x 10(8-5) Hz =0.47 x103 Hz = 4.7x102 Hz Calculate the wavelength of radiation with a frequency of 8.0 x 1014 Hz. w=c/f =3.00x108/8.0*1014 =0.375x10(8-14) m =0.375x10-6 m =3.75X10-7 m Calculating Energy & Frequency of EM radiation Defining variables Frequency (Hz) = f Energy (Joules) = J Plancks constant = h = 6.626 x 10-34 Joules*s Deriving equations Given the formula Energyphoton = h * F (aka Energyphoton = h * )? What is the formula for calculating F (aka )? F = Energyphoton /h Calculating Energy and Frequency (F) Show your work! Calculate the energy of a photon of radiation with a frequency of 8.5 x 1014 Hz. Energyphoton = 8.5 x 1014 Hz x 6.626 x 10-34 Joules*s = 56.321x10(14+-34) =56.321x10-20 Joules = 3.332x10-19 Joules Calculate the energy of a gamma ray photon whose frequency is 5.02 x 1020 Hz? Energyphoton = 5.02 x 1020 Hz x 6.626 x 10-34 Joules*s = 33.2x10(20--34) = 33.32x10(14+-34) = 33.32x10-20 Joules = 3.332x10-19 Joules Calculate the energy of a photon of radiation with a wavelength of 6.4 x 10-7 m. 1st, need frequency f= c/w= 3.00x108/6.4*10-7 = .468 x 10*(8--7) = .468x1015 = 4.68x1014 Hz 2nd, use 4.68x1014 Hz to calculate energy Energyphoton = 4.68x1014 x 6.626 x 10-34 Joules 44.26168 x 10(14+-34) Joules = 44.26168 x 10-20 Joules = 4.426168 x 10-19 Joules What is the energy of light whose wavelength is 4.06 x 10-11 m? 1st, need frequency f= c/w = 3.00x108/4.06*10-11 = .738 x 10*(8--11) = .738 x 1019 = 7.38x1019 Hz 2nd, use this frequency to calculate for Energy Energyphoton = 7.38x1019 x 6.626 x 10-34 = 48.89988 x 10(19+-34) Joules = 48.89988 x 10-15 4.89988x10-14 General Knowledge *,02Fdf  . 2 4 6 ⯚p[pH5%h:hGB*CJOJQJaJph%h:h,tB*CJOJQJaJph(h:h,t6B*CJOJQJaJph(h:h,t6B*CJOJQJaJph(h:hG6B*CJOJQJaJph(h:h,t6B*CJOJQJaJph(h:hG>*B*CJ OJQJaJ$phh:hU4CJ OJQJaJ h:h&CJ OJQJaJ h:h\CJ OJQJaJ h:h4BCJ OJQJaJ f6 ` J j & F <YD<gd; 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What is the relationship between frequency and wavelength? (Direct or Inverse) inverse What is the relationship between frequency and energy? 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Rp{@Times New RomanL 0Q`2 lP`2 q.1 0r.1XG* Times ew Romanb-'1 z%1 @0dv% % % Rp{@"ArialL 0Q`2 lP`2 q.1 Qr.1*X3. * Arial`2_`2܎U|Qb-'1 z%1 @Qdv% % % % % %  TXP@T@LPI.4!% % % TTOW@T@LP A% % % TXP @T@X LdCalculating `C%;J%C,%JC!T Pk@T@  L`FrequencyQ<;KJ;J;CTTlP@T@lLP @!TXP@T@LP& o!TTP@T@LPW@TP @T@ L`avelength CC;%;KC,J!T P~@T@ Llof EM radiationC,!Y~!;CJ%C,&CJTTP@T@LP HRp@Times New RomanL 0Q`2 lP`2 q.1 ,r.1XG* Times ew RomanT-'1 z%1 @,dv% % % Rp@"ArialL 0Q`2 lP`2 q.1 $r.1*X3. * Arial`2@`2܎U$L`-'1 z%1 @$dv% % % Rp{@Times New Roman Q`2x dlP`2x q.1x 8r.1XG* Times ew RomanU-'1 z%1 8dv% % %  % % % TXM2@T@LPA.T% % % TT3LW@T@3LP %Rp{@Times New Roman pQ`2 XlP`2 q.1 |-r.1XG* Times ew RomanU-'1 XXz%1 |-dv% % % % % % TX>4@T@XLpDefining variables`;-%C%CC!C;,%;C%;4'% LdX4X!??% ( TT5>p@T@5LP <Rp@Times New RomanL 0Q`2 lP`2 q.1 |r.1XG* Times ew RomanU-'1 z%1 @|dv% % % Rp @"ArialL 0Q`2 lP`2 q.1 ?r.1*X3. * Arial`2`2܎Ul?HU-'1 z%1 @?dv% % %  % % % TX+2@T@}LPa..% % % TT3*@T@3}LP Q% % % T+@T@} L`Example: 8).B.(TT+D@T@}LP KRp @BLucida Calligraphy&tQ`2tl&XlP`2tl q.1lt r.1"X*MNLucidaCalligraphy-'1 z%1 dv% % % Rp @Cambria MathtQ`2tlXlP`2tl q.1lt L*r.1)X"A B&" WMFC Cambri MathU,*0V-'1 z%1 L*dv% % % % % %  Th. @T@/LWhat is the variable that we use to represent fK..$.().#.-)..=).$).#).$($)-T % @T@  Lhrequency (Hz)$).-).()B$TT& S @T@& LP?@.TTT j @T@T LP @TXk  @T@k LP= >% % % Tx @T@ L\F (aka F >9>% % % Rp @Cambria MathtQ`2tlXlP`2tl q.1lt L*r.1)XA BCambri MahU,*0V-'1 O1^Zwp$wd^O1dv% %  TXt@T@LP)2& % ( % % % TTp@T@pLP?-% % % TT@T@LP 0Rp @Times New RomanL 0Q`2 lP`2 q.1 Rr.1XG* Times ew RomanU-'1 z%1 @Rdv% % % Rp @"ArialL 0Q`2 lP`2 q.1 3r.1*X3. * Arial`2`2܎U3d-'1 z%1 @3dv% % % Rp@Times New Roman Q`2x dlP`2x q.1x @r.1XG* Times ew Romanb-'1 z%1 @dv% % % % % %  TXf2@T@LPb..% % % TT3e@T@3LP Q% % % Thf5 @T@/LWhat is the variable that we use to represent wW.)$.(-))-).(A).$).).)$(.BT6 f4 @T@6  Lhavelength (m))-)).-.FTT5 fK @T@5 LP %1TXL f @T@L LP= 4% % % TT d @T@ LPw@B% % % TT f @T@ LP ) % % % TX%-@T@wLPc.)% % % TT.$@T@.wLP @V% % % T%@T@wLpWhat is the variaW.)$.(-))T% @T@wLble that we use to represent -).(A).$).).)$(.TT %= @T@ wLP K % % % T@T@L|Speed of Light (m/s) = 3.)).-8-.F$4% % % TT@T@LPc@(% % % TT@T@LP TTh@T@LP K Tpf^@T@ILXNote: B.)Rp@Times New Roman pQ`2 XlP`2 q.1 Dr.1XG* Times ew Romana-'1 XXz%1 Ddv% % % % % % T`g^@T@gILTall)'% LdgSVgS\!??% ( TT^@T@ILP Tf ^@T@I9LElectromagnetic Spectrum Waves travel at this same speed8)).F)-.))2.)).FW)-)$)-)(-$#)F)$.))-TTg  ^@T@g ILP a)Rp@Times New RomanP 4Q`2 lP`2 q.1 "r.1XG* Times ew RomanT`-'1 z%1 D"dv% % % % % %  % % % TX2@T@LPd..% % % TT3@T@3LP Q% % % Tf @T@>LSpeed of light is a constant. How many m/s does light travel? 3.)).--.$))-.&" WMFC u#).B.BF)/-F$..)$-.)-))% % % Txg  @T@g L\3.00*10......% % % TT  @T@ LP8T% % % TT  @T@ LP T)Rpj@Times New Roman Q`2x dlP`2x q.1x r.1XG* Times ew Romana-'1 z%1 dv% % %  % % % TX, @T@LPB.N% % % TT-W @T@-LP T+% % % TXu @T@X L`Deriving e`;,%C%CC!;Txu @T@L\quationCC;%%CCTTuQ @T@LPsT3'% LdXQX!??% ( % % % TTRf @T@RLP TD% % % Rp@BLucida Calligraphy&tQ`2tl&XlP`2tl q.1lt r.1"X*MNLucidaCalligraphy-'1 z%1 dv% % % Rp@Cambria MathtQ`2tlXlP`2tl q.1lt | r.1)X"A BCambri MathU\ pV-'1 z%1 | dv% % %  % % % TlXm 7 @T@X LXGivenB-).TT8m N @T@8 LP LTpOm " @T@O LXthe fo.).Tp#m  @T@# LXrmula F.)Tpm d @T@ LX& & C = [\=3% % % TTef  @T@e LPFF% % % TTm  @T@ LP*.% % % TTf N @T@ LPWBkTTDf b @T@D LP Tcf  @T@c L`(aka c = >9>1:% % %  Rp@Cambria MathtQ`2tlXlP`2tl q.1lt | r.1)XA BCambri MahU\ pV-'1 O1^Zwp$w 4O1dv% %  Td @T@ LT*)2'-% % ( % % % TT m @T@ LP S ) % % % TX?  @T@ LP1..% % % TT> W @T@ LP Q% % % T$X? t @T@X $LWhat is the formula for calculating W.)$.(-F.).)().(.-% % % TTu8  @T@u LPFFTT8  @T@ LP 7Tl8  @T@ LX(aka  =:=% % %  Rp@Cambria MathtQ`2tlXlP`2tl q.1lt | r.1)XA BCambri MahU\ pV-'1 O1^Zwp$wd4O1dv% %  TXr $ s @T@ LP)2& % ( % % % TT% 8 V @T@% LP? -TTR 8 _ @T@R LP TT` 8 @T@` LPF F% % % TX ? @T@ LP TX ?  @T@ LP= 4% % % TT = G @T@ LPc\ )TXH = @T@H LP/wB% % % TT ? @T@ LP ) % % % TX x @T@c LP2..% % % TT Wv @T@c LP Q% % % T X ]x @T@Xc #LWhat is the formula for calculatingrW.)$.(-F.).)().(.-% % % TT^ { @T@^c LP TT|  @T@|c LPWjTT  @T@c LP gTT - @T@c LP( % % % %c Rp@Cambria MathtQ`2tlXlP`2tl q.1lt | r.1)XA B&" WMFC UCambri MahU\ pV-'1 O1^Zwp$w4O1dv% %  TX%D wE @T@%c LP)-& % ( % % % TTx x @T@xc LP? (TT _ x @T@c LP ?TT`  x @T@` c LP ,% % % TT  @T@ c LPW k% % % TX  $ x @T@ c LP TX%  n x @T@% c LP= 4% % % T`o  v @T@o c LTc/f)% % % TT  x @T@ c LP ) % % % TX ,k @T@P LPC.N% % % TT- Wi @T@-P LP +Rp@@Lucida Calligraphy&lQ`2&TlP`2 q.1 <:r.1"X*MNLucidaCalligraphy-'1 TTz%1 |<:dv% % % % % % TX _o @T@XP L|Calculating Frequency (XY;%;C%;%%CC!J,;CC;C;B!-% % % TT` m @T@`P LPF FTX m @T@P LP) % % % T l o @T@P Lland Wavelength " ;CC!};C;&;CC%C!TTm o @T@m P LP(K,% % % TX % m @T@ P LPW)k '% LdX] # b X] !??% ( TT$ n m @T@$ P LP K% % %  Rp@ Arial pQ`2 XlP`2 q.1 r.1*X3. * Arial`2``2Ul hV-'1 XXz%1  dv% % % % % % TXs  @T@X LlShow your work! =33A-33A3/TTs  @T@ LP 2Ts @T@ LUse a calculator and do the B.33-3.3333323333T s @T@ Ldactual math 2.23M32TT s @T@ LP 83TT s @T@ LP  TH s / @T@ *Ldon t just leave the answer as a fraction!2333-33-33233.A33.23-33'% LdX / X !??% ( % % % TT0O k @T@0 LP T<Rp@Times New RomanP 4Q`2 lP`2 q.1 l=r.1XG* Times ew Roman_-'1 z%1 Dl=dv% % % % % %  % % % TX0  @T@ LP1..% % % TT/ W @T@ LP 8UQ% % % THX0 \ @T@X *LViolet light has a wavelength of 4.10 x 10C-(-..($)B)-)).-........% % % TT]# oe @T@]X LP-% % % TXp# e @T@pX LP12% % % TT0  @T@ LP 3T0 \ @T@ L|m. What is the frequencyFW.)$.))..(.)-TT] 0 @T@] LP?B )TT 0 @T@ LP [ K % % % TlX .@T@X LXf=c/w 3)BTT/ y@T@/ LP K % % % T|Xj@T@XWL\=3.00*104......% % % TT 9@T@-LP8H% % % T|j@T@WL\/4.10x10...-..% % % TX P9@T@-LP12% % % TTQgj@T@QWLP %TThj@T@hWLP \K % % % TTXl@T@XLP=4TTl@T@LP TTTl@T@LP0T.T`lC@T@LT.73..TTDlZ@T@DLP T`[l@T@[L&" WMFC 5Tx10-..% % % TX`@T@LP20% % % TX`;@T@LP % % % TT<`w@T@<LP < % % % TTX<@T@X)LP=4Tp<@T@)LX7.3*10.....% % % TX @T@LP19% % % TT @T@LP % % % TT<@T@)LPmL% % % TTF>@T@)LP ) % % % TX@T@LP2..% % % TTW@T@LP Q% % % T<X@T@X(LGreen light has a frequency of 6.01 x 10B)).-.-)$))..)-)-.......% % % TX Y@T@ LP14% % % TTZp@T@ZLP Tqh @T@qLHz. What is the wavelengthB(W.)$.)B)-)(.-.TTi  @T@i LP?%(TT  @T@ LP K % % % TlX.d@T@XQLXf=c/wl 3)BTT/yd@T@/QLP 3K % % % T|Xf@T@XL\=3.00*104......% % % TTZ@T@LP8% % % TTf@T@LP/PTTf@T@LP6.TTf1@T@LP.2TT2f_@T@2LP0T.TT`f@T@`LP1.T`f@T@LTx10T-..% % % TXZP@T@LP14% % % TTQfg@T@QLP TTThf@T@hLP TK % % % TTX7@T@X$LP=T4TX7@T@$LP0..T`Z7@T@$LT499...T`[7@T@[$LT*10...% % % TT@T@LP-% % % TT@T@LP6% % % TT#@T@LP T% % % TT$o7@T@$$LPmLTTp7@T@p$LP TT7@T@$LP K % % % TXX9@T@XLP= 4TX9@T@LP4..TX9C@T@LP99..T`D9@T@DLT*10...% % % TT-o@T@cLP-% % % TT-o@T@cLP7T% % % TT- o@T@cLP T% % % TT 9X@T@ LPmL% % % TTY;@T@YLP ) % % % TX^@T@ILP3..% % % TTW\@T@ILP 8Q% % % TX^@T@XIL|What is the wavelength -W.)$.(B)-)).-.TT^@T@ILP( T?^@T@I L`in meters%.F))$TT@^^@T@@ILP)tTT_u^@T@_ILP ,Tv ^@T@vILxof the electromagnetiT-.)()(.F)-/)T|  ^@T@ IL\c carrie))((T ^@T@ ILxr wave transmitted by B)-)).$F(..-% % % T^@T@ILhThe Sports Fan9.)3-.$3)-'% LdSVS1!??% ( TT ^@T@ILP Tl ^@T@ ILXradioh)-.TT^@T@ILP Rp@Times New Roman tQ`2tl XlP`2tl q.1lt r.1XG* &" WMFC Times ew RomanU-'1 z%1 dv% % % Rp@Times New Roman dQ`2 LlP`2 q.1 l,r.1XG* Times ew Romand-'1 LLz%1 tl,dv% % % % % %  % % % T|Xac@T@XL\station $(-.Tda@T@dLat a frequency of 640 kHz ))).-).)-..-.-B)% % % TTp>@T@LP?|!TT?pW@T@?LP(n% % % TpWa1@T@XLXHint: B.T<2a@T@2(Lconvert kHz into Hz by multiplying by 10).-))#)B$..B$-)B.-(..-).-% % % TTU.@T@LP3n% % % TT/aE@T@/LP.tTT;ad@T@FLP),TTea@T@eLP K % % % T|X1@T@XL\f=6.4x10 4..-..% % % TX@T@LP(3% % % TX@T@LP+2!% % % TT'@T@LP)% % % TT(>1@T@(LP TX?1@T@?LP= 4Tp1@T@LX6.4x10./-..% % % TT@T@LP5% % % TT1@T@LP TT1@T@LP K % % % TTX3@T@XLPw2CT|3@T@L\=3.00x104...-..% % % TT'i@T@]LP8 % % % Tx3+@T@L\/6.4*10 .-...% % % TT,'Hi@T@,]LP5% % % TTI3^@T@ILP TT_3@T@_LP %K % % % TTX@T@XLP02.TT@T@LP.oTx@T@L\47 x 10..-..% % % TT@T@LP(P% % % TT@T@LP8% % % TT@T@LP-Q% % % TT@T@LP5%% % % TT"@T@LP)%% % % TT#9@T@#LP %TX:@T@:LPHzH)TT@T@LP K % % % TXXm@T@XZLP=04.TTm@T@ZLP.UTTm@T@ZLP4n.Tlm@T@ZLX7 x10Q.-..% % % TT<@T@0LP3% % % TTm@T@ZLP LTXpm@T@ZLPHzH(TTqm@T@qZLP K % % % T|Xo@T@XL\= 4.7x104..-..% % % TTc@T@LP2% % % TTo@T@LP TXoB@T@LPHzH(% % % TTCqk@T@CLP ) % % % TX.@T@LP4..% % % TT-W@T@LP Q% % % TX. @T@X:LCalculate the wavelength of radiation with a frequency of =))-)).)B)-)).-.-)-(..B.)(..)-)-.TT . @T@ LP T| . @T@ L\8.0 x 10.....% % % TX !* c@T@ VLP14% % % TT+ .A @T@+ LP T`B . @T@B LTHz.B(TT . @T@ LP K % % % TlX7 &WMFC@T@XLXw=c/fC4)TT/y@T@/LP K % % % TTXg@T@XTLP=4Txg@T@TL\3.00x10...-..% % % TT6@T@*LP8% % % TTg@T@TLP/T`_g@T@TLT8.0..T``g@T@`TLT*10...% % % TX#6@T@*LP14% % % TT$16@T@$*LP % % % TT2m6@T@2*LP < % % % TXXj@T@XLP=04.TTj@T@LP.Tpj@T@LX375x10...-..% % % TX^@T@LP(8% % % TT^&@T@LP-% % % T`'^u@T@'LT14)% % % TTvj@T@vLP :TTj@T@LP TTj@T@LPmLTTj]@T@LP K % % % TXX:@T@X'LP=04.TdZ:@T@'LT.375...T`[:@T@['LTx10-..% % % TT @T@LP-% % % TT @T@LP6% % % TT*:@T@'LP TT+w:@T@+'LPmMTTx:@T@x'LP K % % % TTX<@T@XLP=4Tx<@T@L\3.75X10...B..% % % TT0r@T@fLP-% % % TT0r@T@fLP7% % % TT<@T@LP TT<]@T@LPmL% % % TT^>@T@^LP )% % 666666666666666666666666666666666666 6 66 6  6 66 6  6 66 6  6 66 6  6 66 6 66666666666666666666  m."System--@Times--- 2 WBjName:1   2 W}j 2 WMj________________________________________________ Date____________ Period_____     2 Wj ,j' 2 Xj1 2 X(j ,j' 2 qBj ,j'@Times New Roman---@"Arial------2 djI. --- 2 wj ---2 jCalculating   2  jFrequencyn    2 j 2 j&  2 jW2  javelength   "2 kjof EM radiation    2 6j @Times New Roman---@"Arial---@Times New Roman------2 djA.--- 2 }j @Times New Roman------&2 jDefining variables     - @ !-  2 `j @Times New Roman---@"Arial- - - ---2 ja. - - - 2 j ---2 jExample:    2 j @BLucida Calligraphy- - - @Cambria Math- - - ---R2 /jWhat is the variable that we use to represent f             2 > jrequency (Hz)  2 j? 2 j 2 j= - - - 2 jF (aka 0 - - - @Cambria Math- - .2 j) .-  - - - 2 3j? --- 2 =j @Times New Roman- - - @"Arial---@Times New Roman---- - - 2 Ejb. --- 2 Ej - - - R2 E/jWhat is the variable that we use to represent w             2 EC javelength (m)    2 Ej 2 Ej= --- 2 Ejw- - - 2 Ej - - - 2 ojc. --- 2 oj - - - %2 ojWhat is the varia    72 oRjble that we use to represent           2 o4j - - - .2 jSpeed of Light (m/s) =     --- 2 jc - - - 2 j  2 j 2 jNote:   @Times New Roman---- - - 2 jalle - @ !-  2 j a2 9jElectromagnetic Spectrum Waves travel at this same speed              2 j @Times New Roman------- - - 2 jd. --- 2 j - - - h2 >jSpeed of light is a constant. How many m/s does light travel?            ---2 j3.00*100  --- 2 j8- - - 2 j @Times New Roman------2 djB.--- 2 {j ---2  jDeriving e  2 jquation0   2 [js - @ !- --- 2 gj - - - @BLucida Calligraphy---@Cambria Math---- - - 2 *jGiveno 2 *j 2 *jthe fo  2 *jrmula   2 *jC =   --- 2 *kjF- - - 2 *zj* --- 2 *jW 2 *j 2 * j(aka c =    ---*@Cambria Math--.2 *j*) .-- - - 2 *$j - - - 2 Ydj1. --- 2 Ysj - - - A2 Y$jWhat is the formula for calculating           --- 2 YjF 2 Yj 2 Yj(aka  ---Y@Cambria Math--.2 Yj) .---- 2 Yj? 2 Yj  2 YjF- - - 2 Y#j 2 Y.j= --- 2 Y>jc 2 YGj/w- - - 2 Y[j - - - 2 dj2. --- 2 sj - - - @2 #jWhat is the formula for calculating           --- 2 j  2 jW 2 j  2 j(---@Cambria Math--.2 j) .-- - - 2 j? 2 j + 2 j B--- 2 VjW- - - 2 nj 2 xj= ---2 jc/fa - - - 2 j ---2 djC.--- 2 {j @@Lucida Calligraphy------.2 jCalculating Frequency (       --- 2 jF2 j) ---"2 jand Wavelength     2 j( ---2 jW)- @ !,-  2 j ---@ Arial------"2 jShow your work!     2 j 52 !jUse a calculator and do the          2  jactual math     2 j 2 j J2 *jdont just leave the answer as a fraction!          - @ !- --- 2 j @Times New Roman------- - - 2 dj1. --- 2 sj - - - J2 *jViolet light has a wavelength of 4.10 x 10             --- 2 j----2 j12- - - 2 j /2 jm. What is the frequency   2 j? 2 j ---2 jf=c/w   2 j ---2 /j=3.00*10  --- 2 &j8---2 /j/4.10x10  ---2 &!j12--- 2 /.j  2 /3j --- 2 Fj= 2 Fj  2 Fj0 2 Fj.731 2 Fj 2 Fjx101 ---2 =j20---2 =j --- 2 =j --- 2 ^j= 2 ^j7.3*10  ---2 Tj19--- 2 Tj --- 2 ^jm- - - 2 ^j - - - 2 dj2. --- 2 sj - - - G2 (jGreen light has a frequency of 6.01 x 10          ---2 ~j14- - - 2 j 22 jHz. What is the wavelength      2 j? 2 j ---2 jf=c/w0  2 j ---2 j=3.00*10  --- 2 j8--- 2 j/ 2 j6 2 j. 2 j0 2 j1 2 jx100 ---2 !j14--- 2 .j  2 3j --- 2 j= 2 j0. 2 j4990 2 j*100 --- 2 j---- 2 j6--- 2 j --- 2 jm 2 j  2 j ---2 j= 2 j4. 2 j99 2 j*100 --- 2 j---- 2 j7--- 2 j --- 2 jm- - - 2 j - - - 2 dj3. --- 2 sj - - - .2 jWhat is the wavelength       2 Jj(2 P jin meters    2 j) 2 j +2 jof the electromagnetih      2 Tjc carrie   ,2 jr wave transmitted by     - - - 2 EjThe Sports Fan   - @ !}E-  2 j 2 jradior  2 j @Times New Roman---@Times New Roman------- - - 2 'jstation   12 'jat a frequency of 640 kHz       --- 2 'j? 2 'j(---2 'jHint:  G2 '(jconvert kHz into Hz by multiplying by 10           --- 2 j3--- 2 '%j. 2 '*j) 2 '1j ---2 ?jf=6.4x10  ---2 5j(3---2 5j+2--- 2 5j)--- 2 ?j 2 ?j= 2 ?j6.4x10  --- 2 5:j5--- 2 ?@j  2 ?Ej --- 2 Vjw2 Vj=3.00x10  --- 2 Mj8---2 Vj/6.4*100  --- 2 M%j5--- 2 V,j  2 V1j --- 2 mj0 2 mj.2 mj47 x 100   --- 2 dj(--- 2 dj8--- 2 dj---- 2 dj5--- 2 dj)--- 2 mj 2 mjHz 2 m j ---2 j=0 2 j. 2 j4 2 j7 x101  --- 2 {j3--- 2 j 2 jHz 2 j ---2 j= 4.7x10   --- 2 j2--- 2 j 2 jHz - - - 2 j - - - 2 dj4. --- 2 sj - - - b2 :jCalculate the wavelength of radiation with a frequency of                 2 ^j 2 cj8.0 x 10    ---2 j14- - - 2 j 2 jHz.   2 j ---2 jw=c/f   2 j --- 2 j= 2 j3.00x100  --- 2 j8--- 2 j/2 j8.00  2 j*100 ---2 j14--- 2 $j --- 2 'j ---2 j=0 2 j.2 j375x10 ---2 j(8--- 2 j----2 j14)x--- 2 j 2  j  2 jm 2  j ---2 $j=0 2 $j.375 2 $jx105 --- 2 j---- 2 j6--- 2 $j  2 $jm 2 $j --- 2 ;j= 2 ;j3.75X100   --- 2 2j---- 2 2j7--- 2 ;j  2 ;jm- - - 2 ;j --jjjjjjiiiiiiiiiihhhhhhhhggggggggggffff՜.+,0\ hp|  %  &Worksheet frequency/wavelength/Energy3Calculating Frequency & Wavelength of EM radiation Title Headings  !"#$%&')*+,-./0123456789:;<=>?@ABCDEGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~Root Entry FX1Table(:WordDocument8NSummaryInformation(F'DocumentSummaryInformation8CompObjy  F'Microsoft Office Word 97-2003 Document MSWordDocWord.Document.89q