34Electromagnetic Waves
CHAPTER OUTLINE
34.1 Displacement Current and the General Form of Ampère’s Law
34.2 Maxwell’s Equations and Hertz’s Discoveries
34.3 Plane Electromagnetic Waves34.4 Energy Carried by
Electromagnetic Waves34.5 Momentum and Radiation
Pressure34.6 Production of Electromagnetic
Waves by an Antenna 34.7 The Spectrum of Electromagnetic
Waves
ANSWERS TO QUESTIONS
*Q34.1 Maxwell included a term in Ampère’s law to account for the contributions to the magnetic fi eld by changing electric fi elds, by treating those changing electric fi elds as “displacement currents.”
*Q34.2 No, they do not. Specifi cally, Gauss’s law in magnetism prohibits magnetic monopoles. If magnetic monopoles existed, then the magnetic fi eld lines would not have to be closed loops, but could begin or terminate on a magnetic monopole, as they can in Gauss’s law in electrostatics.
Q34.3 Radio waves move at the speed of light. They can travel around the curved surface of the Earth, bouncing between the ground and the ionosphere, which has an altitude that is small when compared to the radius of the Earth. The distance across the lower forty-eight states is approximately 5 000 km, requiring a transit time of
5 10
106
2××
−m
3 10 m ss8 ~ . To go halfway around the Earth
takes only 0.07 s. In other words, a speech can be heard on the other side of the world before it is heard at the back of a large room.
Q34.4 Energy moves. No matter moves. You could say that electric and magnetic fi elds move, but it is nicer to say that the fi elds at one point stay at that point and oscillate. The fi elds vary in time, like sports fans in the grandstand when the crowd does the wave. The fi elds constitute the medium for the wave, and energy moves.
Q34.5 The changing magnetic fi eld of the solenoid induces eddy currents in the conducting core. This is accompanied by I R2 conversion of electrically-transmitted energy into internal energy in the conductor.
*Q34.6 (i) According to f LC= − −( ) ( ) ,/2 1 1 2π to make f half as large, the capacitance should be made four times larger. Answer (a).
(ii) Answer (b).
*Q34.7 Answer (e). Accelerating charge, changing electric fi eld, or changing magnetic fi eld can be the source of a radiated electromagnetic wave.
*Q34.8 (i) Answer (c). (ii) Answer (c). (iii) Answer (c). (iv) Answer (b). (v) Answer (b).
*Q34.9 (i) through (v) have the same answer (c).
271
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272 Chapter 34
Q34.10 Sound
The world of sound extends to the top of the atmosphere and stops there; sound requires a material medium. Sound propagates by a chain reaction of density and pressure dis-turbances recreating each other. Sound in air moves at hundreds of meters per second. Audible sound has frequencies over a range of three decades (ten octaves) from 20 Hz to 20 kHz. Audible sound has wavelengths of ordinary size (1.7 cm to 17 m). Sound waves are longitudinal.
Light
The universe of light fi lls the whole universe. Light moves through materials, but faster in a vacuum. Light propagates by a chain reac-tion of electric and magnetic fi elds recreating each other. Light in air moves at hundreds of millions of meters per second. Visible light has frequencies over a range of less than one octave, from 430 to 750 Terahertz. Visible light has wavelengths of very small size (400 nm to 700 nm). Light waves are transverse.
Sound and light can both be refl ected, refracted, or absorbed to produce internal energy. Both have amplitude and frequency set by the source, speed set by the medium, and wavelength set by both source and medium. Sound and light both exhibit the Doppler effect, standing waves, beats, interference, diffraction, and resonance. Both can be focused to make images. Both are described by wave functions satisfying wave equations. Both carry energy. If the source is small, their intensities both follow an inverse-square law. Both are waves.
Q34.11 The Poynting vector �S describes the energy fl ow associated with an electromagnetic wave. The
direction of �S is along the direction of propagation and the magnitude of
�S is the rate at which
electromagnetic energy crosses a unit surface area perpendicular to the direction of �S .
*Q34.12 (i) Answer (b). Electric and magnetic fi elds must both carry the same energy, so their amplitudes are proportional to each other. (ii) Answer (a). The intensity is proportional to the square of the amplitude.
*Q34.13 (i) Answer (c). Both the light intensity and the gravitational force follow inverse-square laws.
(ii) Answer (a). The smaller grain presents less face area and feels a smaller force due to light pressure.
Q34.14 Photons carry momentum. Recalling what we learned in Chapter 9, the impulse imparted to a particle that bounces elastically is twice that imparted to an object that sticks to a massive wall. Similarly, the impulse, and hence the pressure exerted by a photon refl ecting from a surface must be twice that exerted by a photon that is absorbed.
Q34.15 Different stations have transmitting antennas at different locations. For best reception align your rabbit ears perpendicular to the straight-line path from your TV to the transmitting antenna. The transmitted signals are also polarized. The polarization direction of the wave can be changed by refl ection from surfaces—including the atmosphere—and through Kerr rotation—a change in polarization axis when passing through an organic substance. In your home, the plane of polar-ization is determined by your surroundings, so antennas need to be adjusted to align with the polarization of the wave.
Q34.16 Consider a typical metal rod antenna for a car radio. The rod detects the electric fi eld portion of the carrier wave. Variations in the amplitude of the incoming radio wave cause the electrons in the rod to vibrate with amplitudes emulating those of the carrier wave. Likewise, for frequency modulation, the variations of the frequency of the carrier wave cause constant-amplitude vibra-tions of the electrons in the rod but at frequencies that imitate those of the carrier.
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Electromagnetic Waves 273
*Q34.17 (i) Gamma rays have the shortest wavelength. The ranking is a < g < e < f < b < c < d.
(ii) Gamma rays have the highest frequency: d < c < b < f < e < g < a.
(iii) All electromagnetic waves have the same physical nature. a = b = c = d = e = f = g.
Q34.18 The frequency of EM waves in a microwave oven, typically 2.45 GHz, is chosen to be in a band of frequencies absorbed by water molecules. The plastic and the glass contain no water molecules. Plastic and glass have very different absorption frequencies from water, so they may not absorb any signifi cant microwave energy and remain cool to the touch.
Q34.19 People of all the world’s races have skin the same color in the infrared. When you blush or exercise or get excited, you stand out like a beacon in an infrared group picture. The brightest portions of your face show where you radiate the most. Your nostrils and the openings of your ear canals are bright; brighter still are just the pupils of your eyes.
Q34.20 Light bulbs and the toaster shine brightly in the infrared. Somewhat fainter are the back of the refrigerator and the back of the television set, while the TV screen is dark. The pipes under the sink show the same weak sheen as the walls until you turn on the faucets. Then the pipe on the right turns very black while that on the left develops a rich glow that quickly runs up along its length. The food on your plate shines; so does human skin, the same color for all races. Clothing is dark as a rule, but your bottom glows like a monkey’s rump when you get up from a chair, and you leave behind a patch of the same blush on the chair seat. Your face shows you are lit from within, like a jack-o-lantern: your nostrils and the openings of your ear canals are bright; brighter still are just the pupils of your eyes.
Q34.21 12.2-cm waves have a frequency of 2.46 GHz. If the Q value of the phone is low (namely if it is cheap), and your microwave oven is not well shielded (namely, if it is also cheap), the phone can likely pick up interference from the oven. If the phone is well constructed and has a high Q value, then there should be no interference at all.
Section 34.1 Displacement Current and the General Form of Ampère’s Law
*P34.1 (a) d
dt
dQ dt IEΦ = = = ( )× ⋅
=−∈ ∈0 012
0 100
8 85 10
.
.
A
C N m2 2111 3 109. × ⋅V m s
(b) Id
dtId
E= ∈ = =0 0 100Φ
. A
*P34.2 d
dt
d
dtEA
dQ dt IEΦ = ( ) =∈
=∈0 0
(a) dE
dt
I
A=
∈= × ⋅
0
117 19 10. V m s
(b) B dsd
dtE⋅ =∈∫� 0 0µ
Φ so 2 0 0
0
2π µ πrB ddt
Q
Ar= ∈
∈⋅
⎡
⎣⎢
⎤
⎦⎥
BIr
A= =
( ) ×( )( )
=−µ µ
π0 0
2
22
0 200 5 00 10
2 0 1002 0
. .
.. 00 10 7× − T
SOLUTIONS TO PROBLEMS
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274 Chapter 34
*P34.3 We use the extended form of Ampère’s law, Equation 34.7. Since no moving charges are present, I = 0 and we have
� �
��B ⋅ = ∈∫ dd
dtEµ0 0
Φ .
In order to evaluate the integral, we make use of the symmetry of the situation. Symmetry requires that no particular directionfrom the center can be any different from any other direction. Therefore, there must be circular symmetry about the central axis. We know the magnetic fi eld lines are circles about the axis. Therefore, as we travel around such a magnetic fi eld circle, the magnetic fi eld remains constant in magnitude. Setting aside until
later the determination of the direction of �B, we integrate
� �� B ⋅∫ dl
around the circle
at R = 0 15. m
to obtain 2π RB
Differentiating the expression ΦE AE=
we have d
dt
d dE
dtEΦ =
⎛⎝⎜
⎞⎠⎟
π 2
4
Thus, � �
��B∫ ⋅ = = ∈⎛
⎝
⎜⎜⎜
⎞
⎠
⎟⎟⎟
d RBd dE
dt2
40 02
π µ π
Solving for B gives BR
d dE
dt=
∈ ⎛
⎝
⎜⎜⎜
⎞
⎠
⎟⎟⎟
µπ
π0 02
2 4
Substituting numerical values, B =×( ) ×( ) ( )⎡⎣ ⎤⎦− −4 10 8 85 10 0 10 207 12 2π πH m F m m V. . mm s
m
⋅( )( ) ( )2 0 15 4π .
B = × −1 85 10 18. T
In Figure P34.3, the direction of the increase of the electric fi eld is out the plane of the paper. By the right-hand rule, this implies that the direction of
�B is counterclockwise.
Thus, the direction of �B at P is upwards .
FIG. P34.3
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Electromagnetic Waves 275
Section 34.2 Maxwell’s Equations and Hertz’s Discoveries
P34.4 (a) The rod creates the same electric fi eld that it would if stationary.We apply Gauss’s law to a cylinder of radius r = 20 cm and length �:
� ��E∫ ⋅ = ∈( ) ° =
∈
dq
E rll
A inside0
0
2 0π λcos
�E =
∈=
×( ) ⋅−λπ2
35 10
0
9
rradially outward
C m N m2
22 8 85 10 0 23 15 1012
3
π . .ˆ . ˆ
×( )( ) = ×− C m N C2 j j
(b) The charge in motion constitutes a current of 35 10 15 10 0 5259 6×( ) ×( ) =− C m m s A. . This current creates a magnetic fi eld.
�B =µπ0
2
I
r =
× ⋅( ) ( )( )
= ×−
−4 10 0 525
2 0 25 25 10
7ππT m A A
m
.
.ˆ .k 77 k̂ T
(c) The Lorentz force on the electron is � � � �F E v B= + ×q q
�F j= − ×( ) ×( )+ − ×
−
−
1 6 10 3 15 10
1 6 10
19 3
1
. . ˆ
.
C N C
99 6
7
240 10
5 25 10
C m s
N s
C m
( ) ×( )× × ⋅
⋅⎛⎝⎜
⎞−
ˆ
. ˆ
i
k⎠⎠⎟
= × −( ) + × +( ) =− −�F j j5 04 10 2 02 10 416 17. ˆ . ˆ N N .. ˆ83 10 16× −( )− j N
*P34.5 � � � � �F a E v B= = + ×m q q
� � � �a E v B= + ×⎡⎣ ⎤⎦
e
m where
� �v B
i j k
× = = − (ˆ ˆ ˆ
. . .
.200 0 0
0 200 0 300 0 400
200 0 400)) + ( )ˆ . ˆj k200 0 300
�a j j k= ×
×− +
−
−
1 60 10
1 67 1050 0 80 0 60 0
19
27
.
.. ˆ . ˆ . ˆ⎡⎡⎣ ⎤⎦ = × − +⎡⎣ ⎤⎦
= ×
9 58 10 30 0 60 0
2 87 10
7
9
. . ˆ . ˆ
.
j k
a� −− +⎡⎣ ⎤⎦ = − × ×( )ˆ ˆ . ˆ ˆj k j k2 2 87 109m s + 5.75 102 9 m s2
*P34.6 � � � � �F a E v B= = + ×m q q so �
� � �a E v B= − + ×⎡⎣ ⎤⎦
e
m where
� �v B
i j k
j× = = −
ˆ ˆ ˆ
.
.
. ˆ10 0 0 0
0 0 0 400
4 00
�a i j=
− ×( )×
+ −−
−
1 60 10
9 11 102 50 5 00 4 0
19
31
.
.. ˆ . ˆ . 00 1 76 10 2 50 1 00
4
11ˆ . . ˆ . ˆj i j
a
⎡⎣ ⎤⎦ = − ×( ) +⎡⎣ ⎤⎦
= −� .. ˆ . ˆ39 10 1 76 1011 11× − ×( )i j m s2
FIG. P34.4
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276 Chapter 34
Section 34.3 Plane Electromagnetic Waves
P34.7 (a) Since the light from this star travels at 3 00 108. × m s
the last bit of light will hit the Earth in 6 44 10
2 15 10 68018
10. .××
= × =m3.00 10 m s
s year8 ss.
Therefore, it will disappear from the sky in the year 2 007 680 2 69 103+ = ×. A.D. The star is 680 light-years away.
(b) ∆ ∆t x= = ××
= =v
1 496 10499 8 31
11..
m
3 10 m ss min8
(c) ∆ ∆t x= =×( )
×=
v
2 3 84 10
3 102 56
8
8
..
m
m ss
(d) ∆ ∆t x= =×( )
×=
v
2 6 37 10
3 100 133
6
8
π ..
m
m ss
(e) ∆ ∆t x= = ××
= × −v
10 103 33 10
35m
3 10 m ss8 .
P34.8 v =∈
= = = ×1 11 78
0 750 2 25 100 0
8
κµ .. .c c m s
P34.9 (a) f cλ = or f 50 0 3 00 108. .m m s( ) = ×
so f = × =6 00 10 6 006. .Hz MHz
(b) E
Bc= or 22 0 3 00 108. .
maxB= ×
so �B kmax . ˆ= −73 3 nT
(c) k = = = −2 250 0
0 126 1πλ
π.
. m
and ω π π= = ×( ) = ×−2 2 6 00 10 3 77 106 1 7f . .s rad s
� �B B= −( ) = − − ×max cos . cos . .kx t x tω 73 3 0 126 3 77 107(( ) k̂ nT
P34.10 E
Bc= or 220 3 00 108
B= ×.
so B = × =−7 33 10 7337. T nT
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Electromagnetic Waves 277
P34.11 (a) BE
c= =
×= × =−100
3 00 103 33 10 0 333
87V m
m sT T
.. . µ
(b) λ π π µ= =×
=−2 2
1 00 100 628
7 1k ..
mm
(c) fc= = ×
×= ×−λ
3 00 10
6 28 104 77 10
8
714.
..
m s
mHz
P34.12 E E kx t= −( )max cos ω
∂∂
= − −( ) ( )
∂∂
= − −( )
E
xE kx t k
E
tE kx t
max
max
sin
sin
ω
ω −−( )
∂∂
= − −( ) ( )∂∂
= −
ω
ω2
22
2
2
E
xE kx t k
E
tE
max
max
cos
ccos kx t−( ) −( )ω ω 2
We must show: ∂∂
= ∈ ∂∂
E
x
E
t2 0 02
2µ
That is, −( ) −( ) = − ∈ −( ) −(k E kx t E kx t2 0 0 2max maxcos cosω µ ω ω ))
But this is true, because k
f c
2
2
2
2 0 0
1 1
ω λµ= ⎛
⎝⎜⎞⎠⎟
= = ∈
The proof for the wave of magnetic fi eld follows precisely the same steps.
P34.13 In the fundamental mode, there is a single loop in the standing wave between the plates. Therefore, the distance between the plates is equal to half a wavelength.
λ = = ( ) =2 2 2 00 4 00L . .m m
Thus, fc= = × = × =λ
3 00 10
4 007 50 10 75 0
87.
.. .
m s
mHz MHz
P34.14 dA to A cm= ± =6 5 2%
λ
λ
λ
= ±
= = ±( ) ×( ) =−12 5
0 12 5 2 45 10 29 1cm
m s
%
. % . .v f 99 10 58× ±m s %
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278 Chapter 34
Section 34.4 Energy Carried by Electromagnetic Waves
P34.15 S IU
At
Uc
Vuc= = = = Energy
Unit Volume
W m
m s
2
= = =×
=u Ic
1 000
3 00 103
8...33 J m3µ
P34.16 Srav
W
4 4.00 1 609 m= = ×
×( )=P
4
4 00 107 682
3
2π πµ. . WW m2
E cSmax .= =2 0 076 10µ av V m
∆V E Lmax max . . .= = ( )( ) =76 1 0 650 49 5mV m m mV ampllitude( ) or 35.0 mV (rms)
P34.17 r = ( )( ) = ×5 00 1 609 8 04 103. .mi m mi m
Sr
= = ××( )
=P4
250 103072
3
2π πµW
4 8.04 10 WW m
3
2
*P34.18 (a) P
area
energy
area
kWh
30 d m=
⋅=
( )( )∆t600
13 9 5. mm
J s h
30 d 123.5 m
d
24 h2( )=
× ( )( )
⎛⎝⎜
⎞⎠
600 10 13⎟⎟ = 6 75. W m2
(b) The car uses gasoline at the rate
55mi hgal
25 mi( )⎛⎝
⎞⎠ . Its rate of energy conversion is
P = × ⎛⎝⎜
⎞⎠⎟( )44 10 2 54 556 J kg kg
1 galmi h
gal
25
.
mmi
h
3 600 sW⎛⎝⎜
⎞⎠⎟⎛⎝⎜
⎞⎠⎟= ×1 6 83 104. . Its power-
per-footprint-area is
Parea
W
2.10 m 4.90 mW m2= ×
( )= ×6 83 10 6 64 10
43. . .
(c) For an automobile of typical weight and power to run on sunlight, it would have to carry a solar panel huge compared to its own size. Rather than running a conventional car, it is much more natural to use solar energy for agriculture, forestry, lighting, space heating, drying, water purifi cation, water heating, and small appliances.
P34.19 Power output = (power input)(effi ciency).
Thus, Power inputPower out
eff
W
0.300= = × =1 00 10 3
6..333 106× W
and AI
= = ××
= ×P 3 33 10 3 33 106
3. . W
1.00 10 W m m
3 22
P34.20 IB c
r= =max
2
022 4µ π
P
B
r cmax.
=⎛⎝⎜
⎞⎠⎟⎛⎝⎜
⎞⎠⎟ =
×( )( ) ×P4
2 10 0 10 2 42
0
3
πµ π 110
4 5 00 10 3 00 105 16 10
7
3 2 8
10
−−( )
×( ) ×( )= ×
π . .. T
Since the magnetic fi eld of the Earth is approximately 5 10 5× − T, the Earth’s fi eld is some 100 000 times stronger.
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Electromagnetic Waves 279
P34.21 (a) P = =I R2 150 W
A rL= = ×( )( ) = ×− −2 2 0 900 10 0 080 0 4 52 103 4π π . . .m m m2
SA
= =P 332 kW m2 (points radially inward)
(b) BI
r= = ( )
×( ) =−µπ
µπ
µ0 032
1 00
2 0 900 10222
.
.T
EV
x
IR
L= = = =∆
∆150
1 88V
0.080 0 mkV m.
Note: SEB= =µ0
332 kW m2
P34.22 (a) IE
c= =
×( )× ⋅( ) ×−
max2
0
6 2
7 82
3 10
2 4 10 3 10µ πV m
T m A m s(( ) ⋅⎛⎝
⎞⎠ ⋅
⎛⎝
⎞⎠
⋅ ⋅⋅
⎛⎝
⎞⎠
⋅⎛⎝
⎞⎠
J
V C
C
A s
T C m
N s
N m
J
2
I = ×1 19 1010. W m2
(b) P = = ×( ) ×⎛⎝⎜⎞⎠⎟
= ×−
IA 1 19 105 10
2 34103 2
. .W mm
22 π 1105 W
P34.23 (a) � �E B i j k i⋅ = + −( )( ) ⋅ +80 0 32 0 64 0 0 200 0. ˆ . ˆ . ˆ . ˆ .N C 0080 0 0 290ˆ . ˆj k+( ) Tµ
� �E B⋅ = + −( ) ⋅ ⋅ =16 0 2 56 18 56 0. . . N s C m2 2
(b) � � �S E B
i j k= × =
+ −( )⎡⎣ ⎤⎦ ×1 80 0 32 0 64 0 00µ
. ˆ . ˆ . ˆ N C .. ˆ . ˆ . ˆ200 0 080 0 0 290
4 10 7i j k+ +( )⎡⎣ ⎤⎦
× ⋅−T
T m
µ
π AA
�S
k j k i j=
− − + − +6 40 23 2 6 40 9 28 12 8 5 12. ˆ . ˆ . ˆ . ˆ . ˆ . îi( ) ××
−
−
10
4 10
6
7
W m2
π
�S i j= −( ) =11 5 28 6 30 9. ˆ . ˆ .W m W m2 2 at −68 2. ° from the +x axis
P34.24 The energy put into the water in each container by electromagnetic radiation can be written as e t eIA tP ∆ ∆= where e is the percentage absorption effi ciency. This energy has the same effect as heat in raising the temperature of the water:
eIA t mc T Vc T
TeI t
c
eI t
c
∆ ∆ ∆
∆ ∆ ∆
= =
= =
ρ
ρ ρ�� �
2
3
where � is the edge dimension of the container and c the specifi c heat of water. For the small container,
∆T =×( )
( )( )0 7 25 10 480
0 06 4 186
3.
.
W m s
10 kg m m
2
3 3 J kg CC
⋅=
°°33 4.
For the larger,
∆T =⋅( )
( ) =0 91 25 480
0 12 4 18621 7
.
..
J s m s
m J C
2
2 °°°C
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280 Chapter 34
P34.25 (a) BE
cmaxmax= : Bmax
.
..= ×
×=7 00 10
3 00 102 33
5
8
N C
m smT
(b) IE
c= max
2
02µ: I =
×( )×( ) ×( ) =−7 00 10
2 4 10 3 00 10650
5 2
7 8
.
.πMW m2
(c) IA
= P : P = = ×( ) ×( )⎡⎣⎢⎤⎦⎥=−IA 6 50 10
41 00 10 518 3
2. .W m m2
π00 W
P34.26 (a) E cB= = ×( ) ×( ) =−3 00 10 1 80 10 5408 6. .m s T V m
(b) uB
av3J m= =
×( )×
=−
−
2
0
6 2
7
1 80 10
4 102 58
µ πµ
..
(c) S cuav av2W m= = ×( ) ×( ) =−3 00 10 2 58 10 7738 6. .
*P34.27 (a) We assume that the starlight moves through space without any of it being absorbed. The radial distance is
20 20 1 20 3 10 3 156 10 18 7 ly yr m s s= ( ) = ×( ) ×( ) =c . .889 10
4
4 10
17
2
28
2
×
= = ××( )
=
m
W
4 1.89 10 m17I
r
Pπ π
88 88 10 8. × − W m2
(b) The Earth presents the projected target area of a fl at circle:
P = = ×( ) ×( ) = ×−IA 8 88 10 6 37 10 1 13 108 6 2 7. . .W m m 2 π WW
Section 34.5 Momentum and Radiation Pressure
*P34.28 (a) The radiation pressure is 2 1 370
3 00 109 13 108
6W m
m sN m
2
22( )
×= × −
.. .
Multiplying by the total area, A = ×6 00 105. m2 gives: F = 5 48. N .
(b) The acceleration is: aF
m= = = × −5 48 9 13 10 4. .N
6 000 kgm s2
(c) It will arrive at time t where d at= 12
2
or td
a= =
×( )×( ) = ×−
2 2 3 84 10
9 13 109 17 10
8
4
5.
..
m
m s
2ss days= 10 6.
P34.29 For complete absorption, PS
c= =
×=25 0
3 00 1083 38
.
.. nPa .
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Electromagnetic Waves 281
*P34.30 (a) The magnitude of the momentum transferred to the assumed totally refl ecting surface in time t is p = 2T
ER /c = 2SAt/c. Then the vector momentum is
p�� �= = × −2 2 6 40 10 14S iAt c/ ( ˆ )( )( W/m m s)/(2 2 33 m/s)×108
= × ⋅−1 60 10 10. î kg m/s each second
(b) The pressure on the assumed totally refl ecting surface is P = 2S/c. Then the force is
PAî = 2SAî/c = 2(6 W/m2)(40 × 10–4 m2)(1 s)/(3 × 108 m/s) = 1 60 10 10. ˆ× − i N
(c) The answers are the same. Force is the time rate of momentum transfer.
P34.31 Ir
E
c= =P
π µ22
02max
(a) Ec
rmax.= ( ) =P 2 1 900
2
µπ
kN C
(b) 15 10
3 00 101 00 50 0
3
8
××
( ) =− J s
m sm pJ
.. .
(c) pU
c= = ×
×= × ⋅
−−5 10
3 00 101 67 10
11
819
.. kg m s
*P34.32 (a) The light pressure on the absorbing Earth is PS
c
I
c= = .
The force is F PAI
cR= = ( ) = ×
×π π2
61370 6 37 10( ) ( .W/m m)
3.00
2 2
110 m sN8 = ×5 82 10
8. away
from the Sun.
(b) The attractive gravitational force exerted on Earth by the Sun is
FGM M
rgS M
M
= =× ⋅( ) ×−
2
11 306 67 10 1 991 10. .N m kg k2 2 gg kg
m
( ) ×( )×( )
= ×
5 98 10
1 496 10
3 55 10
24
11 2
22
.
.
. N
which is 6 10 1013. × times stronger and in the oppositee direction compared to the repulsive force in part (a).
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282 Chapter 34
*P34.33 (a) If PS is the total power radiated by the Sun, and rE and rM are the radii of the orbits of the planets Earth and Mars, then the intensities of the solar radiation at these planets are:
IrES
E
= P4 2π
and IrMS
M
= P4 2π
Thus, I Ir
rM EE
M
=⎛⎝⎜
⎞⎠⎟
= ( ) ××
2 11
1 3701 496 10
W mm
2.282 .
110 mW m11
2⎛⎝⎜
⎞⎠⎟
=2
590
(b) Mars intercepts the power falling on its circular face:
PM M MI R= ( ) = ( ) ×( )⎡⎣ ⎤⎦ =π π2 62
590 3 37 10 2 10W m m2 . . ××1016 W
(c) If Mars behaves as a perfect absorber, it feels pressure PS
c
I
cM M= =
and force F PAI
cR
cM
MM= = ( ) = = ×
×=π 2
162 10 107
P ..
W
3.00 10 m s8001 107× N
(d) The attractive gravitational force exerted on Mars by the Sun is
FGM M
rgS M
M
= =× ⋅( ) ×−
2
11 306 67 10 1 991 10. .N m kg2 2 kkg kg
m
( ) ×( )×( )
6 42 10
2 28 10
23
11 2
.
.
= ×1 64 1021. N
which is ~1013 times stronger than the repulsive force of part (c).
(e) The relationship between the gravitational force and the light-pressure force is similar at very different distances because both forces follow inverse-square laws. The force ratios are not identical for the two planets because of their different radii and densities.
P34.34 The radiation pressure on the disk is PS
c
I
c
F
A
F
r= = = =
π 2.
Then Fr I
c= π
2
.
Take torques about the hinge: τ∑ = 0 H H mgr
r Ir
cx y0 0 0
2
( ) + ( ) − + =sinθ π
θ π π= = ( )− −sin sin .1
21
2 70 4 10r I
mgc
m W s s
0.02
2
44 kg m 9.8 m 3 10 m
kg m
W s2 8
2
3( ) ( ) ×( )⎛⎝⎜
⎞11 ⎠⎠⎟
= = °−sin . .1 0 0712 4 09
Section 34.6 Production of Electromagnetic Waves by an Antenna
P34.35 λ = =cf
536 m so h = =λ4
134 m
λ = =cf
188 m so h = =λ4
46 9. m
FIG. P34.34
mg
PA
Hx Hy
r
q
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Electromagnetic Waves 283
P34.36 P = ( )∆VR
2
or P ∝( )∆V 2
∆ ∆V E y Ey y= −( ) ⋅ = ⋅ � cosθ
∆V ∝ cosθ so P ∝ cos2 θ
(a) θ = 15 0. °: P P P= °( ) = =max maxcos . . . %2 15 0 0 933 93 3
(b) θ = 45 0. °: P P P= °( ) = =max maxcos . . . %2 45 0 0 500 50 0
(c) θ = 90 0. °: P P= ( ) =max cos .2 90 0 0°
P34.37 (a) Constructive interference occurs when d ncosθ λ= for some integer n.
cosθ λ λλ
= =⎛
⎝⎜
⎞
⎠⎟ =n
dn n
22
n = ± ±0 1 2, , , …
∴ = =−strong signal @ θ cos ,1 0 90 270� �
(b) Destructive interference occurs when
dn
cosθ λ= +⎛⎝⎞⎠
2 1
2: cosθ = +2 1n
∴ = ±( ) =−weak signal @ θ cos ,1 1 0 180� �
P34.38 For the proton, ΣF ma= yields q B mR
vv
sin .90 02
� =
The period of the proton’s circular motion is therefore: TR m
qB= =2 2π π
v
The frequency of the proton’s motion is fT
= 1
The charge will radiate electromagnetic waves at this frequency, with λπ= = =c
fcT
mc
qB
2
P34.39 (a) The magnetic fi eld �B k= −( )1
2 0µ ωJmax cos ˆkx t applies for x > 0, since it describes a
wave moving in the î direction. The electric fi eld direction must satisfy � � �S E B= ×1
0µ as
ˆ ˆ ˆi j k= × so the direction of the electric fi eld is ĵ when the cosine is positive. For its
magnitude we have E cB= , so altogether we have �E j= −( )1
2 0µ ωc kx tJmax cos ˆ .
receivingantenna∆y
q
FIG. P34.36
FIG. P34.37
continued on next page
ISMV2_5104_ch34.indd 283ISMV2_5104_ch34.indd 283 7/2/07 5:19:55 PM7/2/07 5:19:55 PM
284 Chapter 34
(b) � � �S E B i= × = −( )1 1 1
40 002 2 2
µ µµ ωc kx tJmax cos ˆ
�S i= −( )1
4 02 2µ ωc kx tJmax cos ˆ
(c) The intensity is the magnitude of the Poynting vector averaged over one or more cycles.
The average of the cosine-squared function is 1
2, so I c= 1
8 02µ Jmax .
(d) Jmax = =( )
× ( ) × =−8 8 570
4 10 3 103
07 8
I
cµ πW m
Tm A m s
2
..48 A m
Section 34.7 The Spectrum of Electromagnetic Waves
P34.40 From the electromagnetic spectrum chart and accompanying text discussion, the following identifi cations are made:
Frequency, f Wavelength, λ = cf
Classifi cation
2 Hz = 2 × 100 Hz 150 Mm Radio
2 kHz = 2 × 103 Hz 150 km Radio
2 MHz = 2 × 106 Hz 150 m Radio
2 GHz = 2 × 109 Hz 15 cm Microwave
2 THz = 2 × 1012 Hz 150 mm Infrared
2 PHz = 2 × 1015 Hz 150 nm Ultraviolet
2 EHz = 2 × 1018 Hz 150 pm X-ray
2 ZHz = 2 × 1021 Hz 150 fm Gamma ray
2 YHz = 2 × 1024 Hz 150 am Gamma ray
Wavelengh, l Frequency, f c=λ
Classifi cation
2 km = 2 × 103 m 1.5 × 105 Hz Radio
2 m = 2 × 100 m 1.5 × 108 Hz Radio
2 mm = 2 × 10−3 m 1.5 × 1011 Hz Microwave
2 mm = 2 × 10−6 m 1.5 × 1014 Hz Infrared
2 nm = 2 × 10−9 m 1.5 × 1017 Hz Ultraviolet or X-ray
2 pm = 2 × 10−12 m 1.5 × 1020 Hz X-ray or Gamma ray
2 fm = 2 × 10−15 m 1.5 × 1023 Hz Gamma ray
2 am = 2 × 10−18 m 1.5 × 1026 Hz Gamma ray
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Electromagnetic Waves 285
P34.41 (a) f cλ = gives 5 00 10 3 00 1019 8. .×( ) = ×Hz m sλ : λ = × =−6 00 10 6 0012. .m pm
(b) f cλ = gives 4 00 10 3 00 109 8. .×( ) = ×Hz m sλ : λ = =0 075 7 50. .m cm
P34.42 (a) fc= = ×λ
3 10
1 710
88m s
mHz radio wave
.~
(b) 1 000 pages, 500 sheets, is about 3 cm thick so one sheet is about 6 10 5× − m thick.
f = ×× −
3 00 10
6 1010
8
513. ~
m s
mHz infrared
*P34.43 (a) Channel 4: fmin
= 66 MHz λmax .= 4 55 m
fmax
= 72 MHz λmin .= 4 17 m
(b) Channel 6: fmin
= 82 MHz λmax = 3.66 m
fmax
= 88 MHz λmin = 3.41 m
(c) Channel 8: fmin
= 180 MHz λmax = 1.67 m
fmax
= 186 MHz λmin = 1.61 m
P34.44 The time for the radio signal to travel 100 km is: ∆tr =××
= × −100 10 3 33 103
4m
3.00 10 m ss8 .
The sound wave travels 3.00 m across the room in: ∆ts = = ×−3 00 8 75 10 3
..
m
343 m ss
Therefore, listeners 100 km away will receive the news before the people in the newsroom by a
total time difference of ∆t = × − × = ×− − −8 75 10 3 33 10 8 41 103 4 3. . .s s s.
P34.45 The wavelength of an ELF wave of frequency 75.0 Hz is λ = = × = ×cf
3 00 10
75 04 00 10
86.
..
m s
Hzm.
The length of a quarter-wavelength antenna would be L = × = ×1 00 10 1 00 106 3. .m km
or L = ( )⎛⎝⎜
⎞⎠⎟ =1 000
0 621621 km
mi
1.00 km mi
.
Thus, while the project may be theoretically possible, it is not very practical.
ISMV2_5104_ch34.indd 285ISMV2_5104_ch34.indd 285 7/2/07 5:19:58 PM7/2/07 5:19:58 PM
286 Chapter 34
Additional Problems
P34.46 ω π π= = × = ×− −2 6 00 10 1 88 109 1 10 1f . .s s
kc
= = = ××
= =−2 6 00 10
3 00 1020 0 62 8
9 1
8
πλ
ω π π..
. .s
m smm−1
B
E
cmax ..= =
×=300
3 00 101 008
V m
m sTµ
E x t= ( ) − ×( )300 62 8 1 88 1010V m cos . .
B x t= ( ) − ×( )1 00 62 8 1 88 1010. cos . .Tµ
*P34.47 (a) P = SA: P = ( ) ×( )⎡⎣ ⎤⎦ = ×1 370 4 1 496 10 3 85 10112 26W m m2 π . . W
(b) ScB
= max2
02µ so B
S
cmax .= =
×( )( )×
−2 2 4 10 1 370
3 00 100
7
8
µ π N A W m2 2
m sT= 3 39. µ
SE
c= max
2
02µ so E cSmax . .= = ×( ) ×( )( ) =−2 2 4 10 3 00 10 1 370 1 020 7 8µ π kkV m
*P34.48 Suppose you cover a 1.7 m × 0.3 m section of beach blanket. Suppose the elevation angle of the Sun is 60°. Then the target area you fi ll in the Sun’s fi eld of view is
1 7 0 3 30 0 4. . cos . m m m2( )( ) =�
Now IA
U
At= =P U IAt= = ( ) ( )( )( )⎡⎣ ⎤⎦1 370 0 6 0 5 0 4 3 600 W m m 2 2. . . ss J( ) ~106
*P34.49 (a)
0 x
(d) u
(a) Ey
y
2ll
(b) u E E kxE = ∈ = ∈12 0
2 12 0
2 2max cos ( )
(c) u B B kxE
cB= = =1
2
1
2
1
20
2
0
2 2
0
2
22
µ µ µmaxmaxcos ( ) cos (( ) cos ( )maxkx E kx uE=
∈=
µµ
0 0
0
2 2
2
(d) u u u E kxE B= + = ∈02 2max cos ( )
(e) E E kx Adx Eλλ λ
= ∈ = ∈ +∫ ∫00 2 2 00 2 12 12max maxcos ( ) cos(( )
sin(maxmax
2
4212 0
2
00
2
kx Adx
E A xE A
kkx
[ ]
= ∈ + ∈λ )) sin( ) sin( )max max012 0
2 02
44 0
λ λ π= ∈ + ∈ −[ ]E A E Ak
== ∈12 02E Amax λ
(f) IE
AT
E A
ATcE= =
∈= ∈λ
λ02
12 0
2
2max
max
This result agrees with equation 34.24, IE
c
cE
c
cE= = = ∈max max max2
0
2
02
20 0
02 2 2µ µµµ
.
ISMV2_5104_ch34.indd 286ISMV2_5104_ch34.indd 286 7/2/07 5:19:58 PM7/2/07 5:19:58 PM
Electromagnetic Waves 287
P34.50 (a) FGM m
R
GM
RrS Sgrav = =
⎛⎝
⎞⎠
⎛⎝
⎞⎠
⎡⎣⎢
⎤⎦⎥2 2
34
3ρ π
where M S = mass of Sun, r = radius of particle, and R = distance from Sun to particle.
Since FS r
crad= π
2
,
F
F r
SR
cGM rrad
Sgrav
= ⎛⎝⎞⎠⎛⎝⎜
⎞⎠⎟∝1 3
4
12
ρ
(b) From the result found in part (a), when F Fradgrav = ,
we have rSR
cGM S= 3
4
2
ρ
r =
( ) ×( )× ⋅−
3 214 3 75 10
4 6 67 10
11 2
11
W m m
N m kg
2
2
.
. 22 3kg kg m m s( ) ×( )( ) ×( )=
1 991 10 1 500 3 00 1030 8. .
33 78 10 7. × − m
P34.51 (a) BE
cmaxmax .= = × −6 67 10 16 T
(b) SE
cav2W m= = × −max .
2
0
17
25 31 10
µ
(c) P = = × −S Aav W1 67 1014.
(d) F PAS
cA= = ⎛⎝
⎞⎠ = ×
−av N5 56 10 23. (approximately the
weight of 3 000 hydrogen atoms!)
*P34.52 (a) In E = q/4p∈0r2, the net fl ux is q/∈
0, so
�E = Φ r̂ /4p r2 = (487 N ⋅ m2/C) r̂ /4p r2 = ( . / ) ˆ /38 8
2r r N m C2⋅
(b) The radiated intensity is I = P /4p r2 = E2max
/2m0c. Then
Emax
= (P m0c /2p )1/2/r
= [(25 N ⋅ m/s)(4p × 10–7 T ⋅ m/2p A)(3 × 108 m/s)(1 N ⋅ s/1 T ⋅ C ⋅ m)(1 A ⋅ s/1 C)]1/2/r
= ( . / ) /38 7 r N m C⋅
(c) For 3 × 106 N/C = (38.7 N ⋅ m/C)/r we fi nd r = 12 9. ,µm but the expression in part (b) does not apply if this point is inside the source.
(d) In the radiated wave, the fi eld amplitude is inversely proportional to distance. As the distance doubles, the amplitude is cut in half and the intensity is reduced by a factor of 4. In the static case, the fi eld is inversely proportional to the square of distance. As the distance doubles, the fi eld is reduced by a factor of 4. The intensity of radiated energy is everywhere zero.
FIG. P34.51
ISMV2_5104_ch34.indd 287ISMV2_5104_ch34.indd 287 7/2/07 5:19:59 PM7/2/07 5:19:59 PM
288 Chapter 34
P34.53 u E= ∈12 02max E
umax .= ∈
=2 95 10
mV m
P34.54 The area over which we model the antenna as radiating is the lateral surface of a cylinder,
A r= = ×( )( ) = ×− −2 2 4 00 10 0 100 2 51 102 2π π� . . . m m m22
(a) The intensity is then: SA
= =×
=−P 0 600
23 92.
. .W
2.51 10 mW m2
2
(b) The standard is
0 570 0 5701 00 10 3
. ..
mW cm mW cmW
1.00 mW2 2= ( ) ×⎛
−
⎝⎝⎜⎞⎠⎟
×⎛⎝⎜
⎞⎠⎟
=1 00 101 00
5 704.
..
cm
mW m
2
22
While it is on, the telephone is over the standard by 23 9
5 704 19
.
..
W m
W mtimes
2
2 = .
P34.55 (a) BE
cmaxmax
..= =
×= × −175
3 00 105 83 108
7V m
m sT
k = = =2 20 015 0
419πλ
π. m
rad m ω = = ×kc 1 26 1011. rad s
Since�S is along x, and
�E is along y,
�B must be in the directionz . (That is,
� � �S E B∝ × . )
(b) SE B
av = =max max .2
40 60µ
W m2 �S iav = ( )40 6. ˆW m2
(c) PS
cr= = × −2 2 71 10 7. N m2
(d) aF
m
PA
m= = =
×( )( )∑ −2 71 10 0 7500 500
7. .
.
N m m
kg
2 2
== × −4 06 10 7. m s2
�a i= ( )406 nm s2 ˆ
*P34.56 Of the intensity S = 1 370 W m2
the 38.0% that is refl ected exerts a pressure PS
c
S
cr
1
2 2 0 380= = ( ).
The absorbed light exerts pressure PS
c
S
ca
2
0 620= = .
Altogether the pressure at the subsolar point on Earth is
(a) P P PS
ctotal
2W m= + = =
( )×1 2 8
1 38 1 38 1 370
3 00 10
. .
. mm sPa= × −6 30 10 6.
(b) P
Pa
total
2
2
N m
N m= ×
×= ×−
1 01 10
6 30 101 60 10
5
61.
.. 00 times smaller than atmospheric pressure
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Electromagnetic Waves 289
P34.57 (a) PF
A
I
c= =
F
IA
c c= = =
×= × =−P 100
3 00 103 33 10 1108
7J s
m sN
.. kkg( )a
a = × −3 03 10 9. m s2 and x at=1
22
tx
a= = × =2 8 12 10 22 64. .s h
(b) 0 107 3 00 12 0 107= ( ) − ( ) −( ) = ( ) −kg kg m s kgv v v. . 336 0 3 00. .kg m s kg⋅ + ( )v
v = =36 0110
0 327.
. m s t = 30 6. s
P34.58 The mirror intercepts power P = = ×( ) ( )⎡⎣ ⎤⎦ =I A1 1 3 21 00 10 0 500 785. .W m m W2 π . In the image,
(a) IA2 2
= P : I2 2785
625=( )
=W0.020 0 m
kW m2π
(b) IE
c22
02= max
µso E cImax . .= = ×( ) ×( ) ×( )
=
−2 2 4 10 3 00 10 6 25 100 27 8 5µ π
221 7. kN C
BE
cmaxmax .= = 72 4 Tµ
(c) 0 400. P ∆ ∆t mc T=
0 400 785 1 00 4 186 100. .W kg J kg C C( ) = ( ) ⋅( ) −∆t � � 220 0
3 35 101 07 10 17 8
53
.
.. .
�C
J
314 Ws
( )= × = × =∆t min
P34.59 Think of light going up and being absorbed by the bead which presents a face area π rb2
The light pressure is PS
c
I
c= = .
(a) FI r
cmg r gb b� = = =
π ρ π2
34
3 and I
gc m=⎛⎝⎜
⎞⎠⎟
= ×43
3
48 32 10
1 3
7ρπ ρ
. W m2
(b) P = = ×( ) ×( ) =−IA 8 32 10 2 00 10 1 057 3 2. . .W m m kW2 π
ISMV2_5104_ch34.indd 289ISMV2_5104_ch34.indd 289 7/2/07 5:20:01 PM7/2/07 5:20:01 PM
290 Chapter 34
P34.60 Think of light going up and being absorbed by the bead, which presents face area πrb2 .
If we take the bead to be perfectly absorbing, the light pressure is PS
c
I
c
F
A= = =av � .
(a) F Fg� =
so IF c
A
F c
A
mgc
rg
b
= = =�π 2
From the defi nition of density, ρ π= = ( )
m
V
m
rb4 33
so 1 4 31 3
r mb=
( )⎛⎝⎜
⎞⎠⎟
π ρ
Substituting for rb , Imgc
mgc
m gc= ⎛⎝⎞⎠ =
⎛⎝
⎞⎠
⎛⎝
⎞⎠ =π
π ρ ρπ
ρ43
4
3
4
3
2 3 2 3 1 3 33
4
1 3m
π ρ⎛⎝⎜
⎞⎠⎟
(b) P = IA P =⎛⎝⎜
⎞⎠⎟
4
3
3
4
2 1 3π ρπρ
r gc m
P34.61 (a) On the right side of the equation,C m s
C N m m s
N m C m s
C s m
2 2
2 2
2 2 2 3
2 4 3
( )⋅( )( ) =
⋅ ⋅ ⋅ ⋅⋅ ⋅
2
3 ==⋅ = =N ms
J
sW.
(b) F ma qE= = or aqE
m= =
×( )( )×
=−
−
1 60 10 100
9 11 101
19
31
.
.
C N C
kg..76 1013× m s2
The radiated power is then: P =∈
=×( ) ×( )−q a
c
2 2
03
19 2 13 2
6
1 60 10 1 76 10
6 8 8π π
. .
. 55 10 3 00 1012 83
×( ) ×( )− . = × −1 75 10 27. W
(c) F ma mr
q Bc= =⎛⎝⎜
⎞⎠⎟=v v
2
so v = qBrm
The proton accelerates at ar
q B r
m= = =
×( ) ( ) ( )−v2 2 22
19 2 21 60 10 0 350 0 500
1
. . .
..
.
67 10
5 62 10
27 2
14
×( )= ×
−
m s2
The proton then radiatesP =∈
=×( ) ×( )−q a
c
2 2
03
19 2 14 2
6
1 60 10 5 62 10
6 8 8π π
. .
. 55 10 3 00 101 80 10
12 8 324
×( ) ×( )= ×
−−
.. W
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Electromagnetic Waves 291
P34.62 f = 90 0. MHz, Emax .= × =−2 00 10 2003 V m mV m
(a) λ = =cf
3 33. m
T
f
BE
c
= 1 = × =
= = ×
−
−
1 11 10 11 1
6 67 10
8. .
.maxmax
s ns
112 6 67T pT= .
(b) �E j= ( ) −⎛⎝
⎞⎠2 00 2 3 33 11 1
. cos. .
ˆmV mm ns
π x t
�B k= ( ) −⎛⎝
⎞⎠6 67 2 3 33 11 1
. ˆ cos. .
pTm ns
π x t
(c) IE
c= =
×( )×( ) ×(
−
−max
.
.
2
0
3 2
7 82
2 00 10
2 4 10 3 00 10µ π )) = ×−5 31 10 9. W m2
(d) I cu= av so uav3J m= × −1 77 10 17.
(e) PI
c= =
( ) ×( )×
= ×−
−2 2 5 31 10
3 00 103 54 10
9
817.
.. Pa
P34.63 (a) ε θ= − = − ( )ddt
d
dtBAB
Φcos
ε ω θ ω ω θ= − ( ) = ( )A d
dtB t AB tmax maxcos cos sin cos
ε π π θt fB A f t( ) = 2 2max sin cos ε π θ πt r fB f t( ) = 2 22 2
max cos sin
Thus,
ε π θmax max cos= 2 2 2r f B
where θ is the angle between the magnetic fi eld and the normal to the loop.
(b) If�E is vertical,
�B is horizontal, so the plane of the loop should be vertical
and
the plane should contain the line of sight oof the transmitter .
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292 Chapter 34
P34.64 (a) m V r= =ρ ρ π12
4
33
rm=
⎛⎝⎜
⎞⎠⎟
=( )
( )⎛
⎝⎜
⎞
⎠⎟
6
4
6 8 7
990 4
1 3
ρ π π. kg
kg m3
11 3
0 161= . m
(b) A r= = ( ) =12
4 2 0 161 0 1632 2π π . .m m2
(c) I e T= = × ⋅( )( ) =−σ 4 8 40 970 5 67 10 304 470. . W m K K W m2 4 22
(d) P = = ( ) =IA 470 0 163 76 8W m m W2 2. .
(e) IE
c= max
2
02µ
E cImax = ( ) = ×( ) ×( )(−2 8 10 3 10 4700 1 2 7 8µ π Tm A m s W m2 ))⎡⎣ ⎤⎦ =1 2
595 N C
(f) E cBmax max=
Bmax .= ×=595
3 101 988
N C
m sTµ
(g) The sleeping cats are uncharged and nonmagnetic. They carry no macroscopic current. They are a source of infrared radiation. They glow not by visible-light emission but by infrared emission.
(h) Each kitten has radius rk =( )×
⎛⎝⎜
⎞⎠⎟ =
6 0 8
990 40 072 8
1 3.
.π
m and radiating area
2 0 072 8 0 033 32π . .m m2( ) = . Eliza has area 2 6 5 5
990 40 120
2 3
ππ
..
( )×
⎛⎝⎜
⎞⎠⎟ = m. The
total glowing area is 0 120 4 0 033 3 0 254. . .m m m2 2 2+ ( ) = and has power output
P = = ( ) =IA 470 0 254 119W m m W2 2.
P34.65 (a) At steady state, P Pin out= and the power radiated out is Pout = e ATσ4.
Thus, 0 900 1 000 0 700 5 67 10 8 4. . .W m W m K2 2 4( ) = × ⋅( )−A AT
or T =× ⋅( )
⎡
⎣⎢⎢
⎤
⎦⎥⎥
=−900
0 700 5 67 10388
1 4
W m
W m K
2
2 4. .88 115K = °C
(b) The box of horizontal area A presents projected area A sin .50 0° perpendicular to thesunlight. Then by the same reasoning,
0 900 1 000 50 0 0 700 5 67 10 8. sin . . .W m W m K2 2( ) ° = × ⋅−A 44( )AT 4
or T =( ) °
× ⋅( )⎡
⎣⎢ −
900 50 0
0 700 5 67 10 8W m
W m K
2
2 4
sin .
. .⎢⎢
⎤
⎦⎥⎥
= = °1 4
363 90 0K . C
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Electromagnetic Waves 293
P34.66 We take R to be the planet’s distance from its star. The planet, of radius r, presents a
projected area πr2 perpendicular to the starlight. It radiates over area 4 2πr .
At steady-state, P Pin out= : eI r e r Tin π σ π2 2 44( ) = ( )
eR
r e r T6 00 10
423
2 2 4. ×⎛⎝⎜
⎞⎠⎟( ) = ( )W
4 2ππ σ π
so that 6 00 10 1623 2 4. × =W πσR T
R T= × = ×
× −6 00 10 6 00 1023
4
23
8
. .W
16
W
16 5.67 10 Wπσ π mm K Km Gm
2 4⋅( )( ) = × =310 4 77 10 4 7749. .
P34.2 (a) 7 19 1011. × ⋅V m s (b) 200 nT
P34.4 (a) 3 15. ĵ kN C (b) 525 nTk̂ (c) −483 ĵ aN
P34.6 − −( )4 39 1 76 1011. ˆ . ˆi j m s2
P34.8 2.25 × 108 m/s
P34.10 733 nT
P34.12 See the solution.
P34.14 2 9 10 58. %× ±m s
P34.16 49 5. mV
P34.18 (a) 6.75 W/m2 (b) 6.64 kW/m2 (c) A powerful automobile running on sunlight would have to carry on its roof a solar panel huge compared to the size of the car. Agriculture and forestry for food and fuels, space heating of large and small buildings, water heating, and heating for drying and many other processes are clear present and potential applications of solar energy.
P34.20 516 pT, ~105 times stronger than the Earth’s fi eld
P34.22 (a) 11 9. GW m2 (b) 234 kW
P34.24 33.4°C for the smaller container and 21.7°C for the larger
P34.26 (a) 540 V/m (b) 2.58 �J/m3 (c) 773 W/m2
P34.28 (a) 5.48 N away from the Sun (b) 913 µm/s2 away from the Sun (c) 10.6 d
P34.30 (a) 1.60 × 10−10 î kg⋅m/s each second (b) 1.60 × 10−10 î N (c) The answers are the same. Force is the time rate of momentum transfer.
P34.32 (a) 582 MN away from the Sun (b) The gravitational force is 6.10 × 1013 times stronger and in the opposite direction.
ANSWERS TO EVEN PROBLEMS
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294 Chapter 34
P34.34 4.09°
P34.36 (a) 93 3. % (b) 50 0. % (c) 0
P34.38 2π m ceB
p
P34.40 radio, radio, radio, radio or microwave, infrared, ultraviolet, x-ray, γ -ray, γ -ray; radio, radio, microwave, infrared, ultraviolet or x-ray, x- or γ -ray, γ -ray, γ -ray
P34.42 (a) ~108 Hz radio wave (b) ~1013 Hz infrared light
P34.44 The radio audience gets the news 8 41. ms sooner.
P34.46 E x t= ( ) − ×( )300 62 8 1 88 1010V m cos . . B x t= ( ) − ×( )1 00 62 8 1 88 1010. cos . .Tµ
P34.48 ~106 J
P34.50 (a) See the solution. (b) 378 nm
P34.52 (a) �E = (38.8/r2) r̂ N ⋅ m2/C (b) E
max = (38.7/r) (W⋅T ⋅ m2/A ⋅ s)1/2 = (38.7/r) N ⋅ m/C
(c) 12.9 µm, but the expression in part (b) does not apply if this point is inside the source. (d) In the radiated wave, the fi eld amplitude is inversely proportional to distance. As the distance doubles, the amplitude is cut in half and the intensity is reduced by a factor of 4. In the static case, the fi eld is inversely proportional to the square of distance. As the distance doubles, the fi eld is reduced by a factor of 4. The intensity of radiated energy is everywhere zero in the static case.
P34.54 (a) 23 9. W m2 (b) 4 19. times the standard
P34.56 (a) 6 30. Paµ (b) 1 60 1010. × times less than atmospheric pressure
P34.58 (a) 625 kW m2 (b) 21 7. kN C and 72 4. Tµ (c) 17 8. min
P34.60 (a)
16
9
2 1 3mgc
ρπ
⎛⎝⎜
⎞⎠⎟
(b) 16
9
2 2 1 3
2π ρm r gc⎛⎝⎜
⎞⎠⎟
P34.62 (a) 3 33. m, 11 1. ns, 6 67. pT (b)
�E j=( ) −⎛
⎝⎜⎞⎠⎟
2 00 23 33 11 1
. cos. .
ˆmV mm ns
π x t ;
�B k= ( ) −⎛⎝
⎞⎠6 67 2 3 33 11 1
. ˆ cos. .
pTm ns
π x t (c) 5 31. nW m2 (d) 1 77 10
17. × − J m3
(e) 3 54 10 17. × − Pa
P34.64 (a) 16.1 cm (b) 0 163. m2 (c) 470 W m2 (d) 76.8 W (e) 595 N/C (f) 1 98. Tµ (g) The cats are nonmagnetic and carry no macroscopic charge or current. Oscillating charges
within molecules make them emit infrared radiation. (h) 119 W
P34.66 pr2; 4pr2 where r is the radius of the planet; 4.77 Gm
ISMV2_5104_ch34.indd 294ISMV2_5104_ch34.indd 294 7/2/07 5:20:05 PM7/2/07 5:20:05 PM