Let There Be Light!ggilfoyl/em/slides/light.pdf · Let There Be Light! We now finish our...
Transcript of Let There Be Light!ggilfoyl/em/slides/light.pdf · Let There Be Light! We now finish our...
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Let There Be Light!
We now finish our introduction to elec-tromagnetism by completing the list ofMaxwell’s equations and deriving theproperties of light.
1. Show that Maxwell’s Equations ina charge-free vacuum give rise toseparate differential equations for~E and ~B.
2. Show the solutions to those differ-ential equations are waves.
3. What is the speed of those waves?
4. What constraints are imposed byMaxwell’s equations?
∇ · ~D = ρ
∇ · ~B = 0
∇× ~E = −∂~B
∂t
∇× ~H = ~J +∂ ~D
∂tLet There Be Light!
Light – p.1/21
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Faraday’s Law
A conducting bar moves on two frictionless, paral-lel rails in a uniform magnetic field directed into theplane. The bar has length l and initial velocity ~vi tothe right. What is the electric potential across thebar using the magnetic force law ~Fmag = Q~v × ~B?Faraday’s Law states that
E = −dΦ
dt
where E is the electromotive force or voltage andΦ is the magnetic flux. Does Faraday’s Law agreewith the result for the potential?
Light – p.2/21
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Faraday’s Law
A conducting bar moves on two frictionless, paral-lel rails in a uniform magnetic field directed into theplane. The bar has length l and initial velocity ~vi tothe right. What is the electric potential across thebar using the magnetic force law ~Fmag = Q~v × ~B?Faraday’s Law states that
E = −dΦ
dt
where E is the electromotive force or voltage andΦ is the magnetic flux. Does Faraday’s Law agreewith the result for the potential?
What happens if you change the ~B field?
Light – p.2/21
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Maxwell’s Equations (so far)
∇ · ~E =ρ
ǫ0
∇× ~B = µ0~J
∇× ~E = −∂~B
∂t
∇ · ~B = 0
Gauss’s Law
Ampere’s Law
Faraday’s Law
Martha’s Law
Light – p.3/21
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Vector Identities from Griffith’s Inside Cover
~A · ( ~B × ~C) = ~B · ( ~C × ~A) = ~C · ( ~A × ~B)(1)
~A × ( ~B × ~C) = ~B( ~A · ~C) − ~C( ~A · ~B)(2)
∇(fg) = f∇g + g∇f(3)
∇( ~A · ~B) = ~A × (∇× ~B) + ~B × (∇× ~A) + ( ~A · ∇) ~B + ( ~B · ∇) ~A(4)
∇ · (f ~A) = f(∇ · ~A) + ( ~A · (∇f)(5)
∇ · ( ~A × ~B) = ~B · (∇× ~A) − ~A · (∇× ~B)(6)
∇× (f ~A) = f(∇× ~A) − ~A × (∇f)(7)
∇× ( ~A × ~B) = ( ~B · ∇) ~A − ( ~A · ∇) ~B + ~A(∇ · ~B) − ~B(∇ · ~A)(8)
∇ · (∇× ~A) = 0(9)
∇× (∇f) = 0(10)
∇× (∇× ~A) = ∇(∇ · ~A) −∇2 ~A(11)
Light – p.4/21
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Fixing Ampere’s Law
vd
E
positive negative+
Area = A
i
d
surface for current
z
x
Light – p.5/21
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Fixing Ampere’s Law
vd
E
positive negative+
Area = A
i
d
volume for current
z
x
Light – p.6/21
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Maxwell’s Equations (so far)
∇ · ~E =ρ
ǫ0
∇× ~B = µ0~J
∇× ~E = −∂~B
∂t
∇ · ~B = 0
Gauss’s Law
Ampere’s Law
Faraday’s Law
Martha’s Law
Light – p.7/21
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Evidence for Faraday’s Law
Lenz’s Law.
Measurement by R. C. Nicklin, Am. J. Phys. 54, 422(1986).
Pulse from 2−cm−longmagnet falling througha 0.79−cm−radius coil.
Points calculated with a dipole model.
Light – p.8/21
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Maxwell’s Equations
∇ · ~E =ρ
ǫ0
∇× ~B = µ0~J + µ0ǫ0
∂~E
∂t
∇× ~E = −∂~B
∂t
∇ · ~B = 0
Gauss’s Law
Ampere’s Law
Faraday’s Law
Martha’s Law
Light – p.9/21
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Vector Identities from Griffith’s Inside Cover
~A · ( ~B × ~C) = ~B · ( ~C × ~A) = ~C · ( ~A × ~B)(1)
~A × ( ~B × ~C) = ~B( ~A · ~C) − ~C( ~A · ~B)(2)
∇(fg) = f∇g + g∇f(3)
∇( ~A · ~B) = ~A × (∇× ~B) + ~B × (∇× ~A) + ( ~A · ∇) ~B + ( ~B · ∇) ~A(4)
∇ · (f ~A) = f(∇ · ~A) + ( ~A · (∇f)(5)
∇ · ( ~A × ~B) = ~B · (∇× ~A) − ~A · (∇× ~B)(6)
∇× (f ~A) = f(∇× ~A) − ~A × (∇f)(7)
∇× ( ~A × ~B) = ( ~B · ∇) ~A − ( ~A · ∇) ~B + ~A(∇ · ~B) − ~B(∇ · ~A)(8)
∇ · (∇× ~A) = 0(9)
∇× (∇f) = 0(10)
∇× (∇× ~A) = ∇(∇ · ~A) −∇2 ~A(11)
Light – p.10/21
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Traveling Waves
-10 -5 0 5 100.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
x
fHxL
Offset= 0.
Light – p.11/21
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Traveling Waves
-10 -5 0 5 100.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
x
fHxL
Offset= 5.
Light – p.12/21
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Traveling Waves
-10 -5 0 5 100.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
x
fHxL
Offset= 10.
Light – p.13/21
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Traveling Waves
0.0+5.0+10.0
-10 -5 0 5 100.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
x
fHxL
Offset= 0.
Light – p.14/21
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Electromagnetic Waves
Light – p.15/21
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Electromagnetic Waves
Light – p.15/21
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What Happens to Electromagnetic Waves in Linear Media?
Light – p.16/21
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What Happens to Electromagnetic Waves in Linear Media?
Recall Clausius-Mossotti (CM)
ǫr =1 + 2Nα
3ǫ0
1 − Nα3ǫ0
= 1 + χe
~D = ǫ0ǫr~E = ǫ ~E
and the magnetic susceptibility
χm = − 1
1 + 16πmeRE
2µ0e2
=µ
µ0
− 1
~H =1
µ~B
Light – p.16/21
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What Happens to Electromagnetic Waves in Linear Media?
Recall Clausius-Mossotti (CM)
ǫr =1 + 2Nα
3ǫ0
1 − Nα3ǫ0
= 1 + χe
~D = ǫ0ǫr~E = ǫ ~E
and the magnetic susceptibility
χm = − 1
1 + 16πmeRE
2µ0e2
=µ
µ0
− 1
~H =1
µ~B
In free space with no charge:
∇ · ~E = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~B = µ0ǫ0∂ ~E∂t
Light – p.16/21
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What Happens to Electromagnetic Waves in Linear Media?
Recall Clausius-Mossotti (CM)
ǫr =1 + 2Nα
3ǫ0
1 − Nα3ǫ0
= 1 + χe
~D = ǫ0ǫr~E = ǫ ~E
and the magnetic susceptibility
χm = − 1
1 + 16πmeRE
2µ0e2
=µ
µ0
− 1
~H =1
µ~B
In free space with no charge:
∇ · ~E = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~B = µ0ǫ0∂ ~E∂t
In a medium with no free charge:
∇ · ~D = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~H = ∂ ~D∂t
Light – p.16/21
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What Happens to Electromagnetic Waves in Linear Media?
Recall Clausius-Mossotti (CM)
ǫr =1 + 2Nα
3ǫ0
1 − Nα3ǫ0
= 1 + χe
~D = ǫ0ǫr~E = ǫ ~E
and the magnetic susceptibility
χm = − 1
1 + 16πmeRE
2µ0e2
=µ
µ0
− 1
~H =1
µ~B
In free space with no charge:
∇ · ~E = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~B = µ0ǫ0∂ ~E∂t
In a medium with no free charge:
∇ · ~D = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~H = ∂ ~D∂t
In a linear medium with no free charge:
∇ · ~E = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~B = µǫ ∂ ~B∂t
Light – p.16/21
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What Happens to Electromagnetic Waves in Linear Media?
Recall Clausius-Mossotti (CM)
ǫr =1 + 2Nα
3ǫ0
1 − Nα3ǫ0
= 1 + χe
~D = ǫ0ǫr~E = ǫ ~E
and the magnetic susceptibility
χm = − 1
1 + 16πmeRE
2µ0e2
=µ
µ0
− 1
~H =1
µ~B
In free space with no charge:
∇ · ~E = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~B = µ0ǫ0∂ ~E∂t
In a medium with no free charge:
∇ · ~D = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~H = ∂ ~D∂t
In a linear medium with no free charge:
∇ · ~E = 0 ∇× ~E = − ∂ ~B∂t
∇ · ~B = 0 ∇× ~B = µǫ ∂ ~B∂t
For nitrogen gas (N2):
n(CM) =√
ǫr = 1.0002939
n(measured) = 1.0002982 → 1.0003012
Light – p.16/21
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The Mote in God’s Eye
Described by Robert Heinlein as the finest ScienceFiction book ever, The Mote in God’s Eye by Larry Nivenand Jerry Pournelle is a story about our First Con-tact with an alien civilization. The Moties use a lasercannon to shine light on a solar sail and push itacross a distance of 35 light-years.
Light – p.17/21
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The Mote in God’s Eye
Described by Robert Heinlein as the finest ScienceFiction book ever, The Mote in God’s Eye by Larry Nivenand Jerry Pournelle is a story about our First Con-tact with an alien civilization. The Moties use a lasercannon to shine light on a solar sail and push itacross a distance of 35 light-years.
1. What is the expression for the energy pertime per area transported by EM waves invacuum?
2. What is the expression for the pressure ofthe electromagnetic waves?
3. Assume the sail is 3000 km in diameter, thetotal mass is m = 4.5 × 105 kg, and thecraft accelerates uniformly for 75 years toreach the halfway point. What is the mini-mum laser power required?
4. What is the minimum pressure of the light?
Light – p.17/21
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Vector Identities from Griffith’s Inside Cover
~A · ( ~B × ~C) = ~B · ( ~C × ~A) = ~C · ( ~A × ~B)(1)
~A × ( ~B × ~C) = ~B( ~A · ~C) − ~C( ~A · ~B)(2)
∇(fg) = f∇g + g∇f(3)
∇( ~A · ~B) = ~A × (∇× ~B) + ~B × (∇× ~A) + ( ~A · ∇) ~B + ( ~B · ∇) ~A(4)
∇ · (f ~A) = f(∇ · ~A) + ( ~A · (∇f)(5)
∇ · ( ~A × ~B) = ~B · (∇× ~A) − ~A · (∇× ~B)(6)
∇× (f ~A) = f(∇× ~A) − ~A × (∇f)(7)
∇× ( ~A × ~B) = ( ~B · ∇) ~A − ( ~A · ∇) ~B + ~A(∇ · ~B) − ~B(∇ · ~A)(8)
∇ · (∇× ~A) = 0(9)
∇× (∇f) = 0(10)
∇× (∇× ~A) = ∇(∇ · ~A) −∇2 ~A(11)
Light – p.18/21
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Maxwell’s Equations
∇ · ~E =ρ
ǫ0
∇× ~B = µ0~J + µ0ǫ0
∂~E
∂t
∇× ~E = −∂~B
∂t
∇ · ~B = 0
Gauss’s Law
Ampere’s Law
Faraday’s Law
Martha’s Law
Light – p.19/21
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Light Pressure
n
zx
y
dz
a
b
E
BJ
Light – p.20/21
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Time Averaging
0 2 4 6 8 100.0
0.2
0.4
0.6
0.8
1.0
x-Ωt
cos2Hk
x-Ω
tL
Light – p.21/21