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Chapter 34: Electromagnetic Induction
A time changing magnetic field induces an electric field.
This electric field does not satisfy Coulombs Law
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Faraday’s Discovery
A current in a coil is induced if the magnetic field through the coil is changing in time.
The current can be induced two different ways:
1. By changing the size, orientation or location of the coil in a steady magnetic field.
2. By changing in time the strength of the magnetic field while keeping the coil fixed.
Both cases can be described by the same law:
The “electromotive force” equals the rate of change of magnetic flux.
EMF =ddt
Φ
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The current can be induced two different ways:
1. By changing the size, orientation or location of the coil in a steady magnetic field.
The electromotive force comes from the Lorenz force. Motional EMF
2. By changing in time the strength of the magnetic field while keeping the coil fixed.
In case #2 the electromotive force comes from an electric field. This requires saying that electric fields can appear that do not satisfy Coulomb’s Law!
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Motional EMF
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A square conductor moves through a uniform magnetic field. Which of the figures shows the correct charge distribution on the conductor?
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A square conductor moves through a uniform magnetic field. Which of the figures shows the correct charge distribution on the conductor?
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Resistor R
How much current flows?
How much power is dissipated in R?
Where does this power come from?
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Potential difference on moving conductor
DV = Vtop - Vbottom = -
rE ◊d
rs
bottom
top
Ú = vlB
Current that flows: I =
DV
R=vlB
RWe assume that this current is too small to change B
Power supplied to the resistor Pdissipated = IDV
Force on moving rail due to B
rFmag = I
rl ¥
rB
rFpull = - I
rl ¥
rBPush needed to keep rail moving
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Power needed to keep rail moving
rv ◊
rFpull = I lvB( ) = IDV = Pdissipated
Work done by agent doing the pulling winds up as heat in the resistor
What happens when RÆ 0?
I =
DV
R=vlB
RÆ •
At some point we can’t ignore B due to I.
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Is there an induced current in this circuit? If so, what is its direction?
A. NoB. Yes, clockwiseC. Yes, counterclockwise
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A. NoB. Yes, clockwiseC. Yes, counterclockwise
Is there an induced current in this circuit? If so, what is its direction?
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Magnetic Flux
Φ=
rB ⋅d
rA
S∫
Some surface
Remember for a closed surface Φ=0
rB d
rA
Magnetic flux measures how much magnetic field passes through a given surface
Open surface
rB⋅d
rA—∫ =0
Closed surface
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Suppose the rectangle is oriented do that are parallel
Φ =
rB ⋅d
rA
S∫ =
rB A =
rB ab
Rectangular surface in a constant magnetic field. Flux depends on orientation of surface relative to direction of B
rB and d
rA
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Suppose I tilt the rectangle by an angle
Φ =
rB ⋅d
rA
S∫ =
rB Acosθ
Fewer field lines pass through rectangle
Suppose angle is 90°
Φ =
rB ⋅d
rA
S∫ =
rB Acos90o = 0
drA
rB
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DV = Vtop - Vbottom = -
rE ◊d
rs
bottom
top
Ú = vlB
A suggestive relation
this length is vt A = lvt
Define A to be out of page,
B is into page Φ =
rB ⋅d
rA
S∫ = −
rB A = −
rB lvt
DV = -
dF
dt= vlB
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Example of non-uniform B - Flux near a current carrying wire
Φ =
rB ⋅d
rA
S∫
rB =
μ0 I2πx
x
d
rA =bdx
b
Φ =
rB ⋅d
rA
S∫ = bdx
μ 0I
2π xx=c
x=c+a
∫ =μ 0Ib
2πlnc + a
c
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Eddy currents
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Flux near a pole piece
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A. Fb = Fd > Fa = Fc
B. Fc > Fb = Fd > Fa
C. Fc > Fd > Fb > Fa
D. Fd > Fb > Fa = Fc
E. Fd > Fc > Fb > Fa
A square loop of copper wire is pulled through a region of magnetic field. Rank in order, from strongest to weakest, the pulling forces Fa, Fb, Fc and Fd that must be applied to keep the loop moving at constant speed.
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A. Fb = Fd > Fa = Fc
B. Fc > Fb = Fd > Fa
C. Fc > Fd > Fb > Fa
D. Fd > Fb > Fa = Fc
E. Fd > Fc > Fb > Fa
A square loop of copper wire is pulled through a region of magnetic field. Rank in order, from strongest to weakest, the pulling forces Fa, Fb, Fc and Fd that must be applied to keep the loop moving at constant speed.
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Lenz’s LawIn a loop through which there is a change in magnetic flux, and EMF is induced that tends to resist the change in flux
What is the direction of the magnetic field made by the current I?
A. Into the pageB. Out of the page
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A current-carrying wire is pulled away from a conducting loop in the direction shown. As the wire is moving, is there a cw current around the loop, a ccw current or no current?
A. There is no current around the loop.B. There is a clockwise current around the loop.C. There is a counterclockwise current around the loop.
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A. There is no current around the loop.B. There is a clockwise current around the loop.C. There is a counterclockwise current around the loop.
A current-carrying wire is pulled away from a conducting loop in the direction shown. As the wire is moving, is there a cw current around the loop, a ccw current or no current?
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A conducting loop is halfway into a magnetic field. Suppose the magnetic field begins to increase rapidly in strength. What happens to the loop?
A. The loop is pulled to the left, into the magnetic field.B. The loop is pushed to the right, out of the magnetic field.C. The loop is pushed upward, toward the top of the page.D. The loop is pushed downward, toward the bottom of the
page.E. The tension is the wires increases but the loop does not
move.
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A. The loop is pulled to the left, into the magnetic field.B. The loop is pushed to the right, out of the magnetic field.C. The loop is pushed upward, toward the top of the page.D. The loop is pushed downward, toward the bottom of the
page.E. The tension is the wires increases but the loop does not
move.
A conducting loop is halfway into a magnetic field. Suppose the magnetic field begins to increase rapidly in strength. What happens to the loop?
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Questions:
What will be the direction of B in the gap?If I hold Ip fixed, what will be the current in the loop?If I increase Ip what will be the direction of current in the loop?If I decrease Ip what will be the direction of current in the loop?
A Transformeriron core (not a permanent magnet)
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What will be the direction of B in the gap?
Answer: Down
Primary makes B - up in core, returns through gap.
If I hold Ip fixed what will be the current in the loop?
Answer: Zer, flux through loop is not changing
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If I increase Ip from one positive value to a larger positive value what will be the direction of the current in the loop?
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What if I lower Ip but don’t make it negative. What will be the direction of current in the loop?
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34.6 Induced Electric Field
Time changing magnetic fields induce electric fields
rF =q(
rE +
rv×
rB)
But, the wire is not moving, v=0
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There is an electric field even with no wire.
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EMF = loop
rE +
rv×
rB( )—∫ ⋅d
rS=-
ddt
Φ =−ddt
rB⋅d
rA
Area∫
Faraday’s Law for Moving Loops
related by right hand rule
drS
drA
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Reasons Flux Through a Loop Can Change
A. Location of loop can change
B. Shape of loop can change
C. Orientation of loop can change
D. Magnetic field can change
d
dtΦ =
ddt
rB⋅d
rA
Area∫
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Faraday’s Law for Stationary Loops
loop
rE⋅d
rS—∫ ==−
∂rB∂t
⋅drA
Area∫
EMF = loop
rE +
rv×
rB( )—∫ ⋅d
rS=-
ddt
Φ =−ddt
rB⋅d
rA
Area∫
Faraday’s Law for Moving Loops
Only time derivative of B enters
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There is an electric field even with no wire.
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Call component of E in direction E(r,t)
Faraday’s Law for Stationary Loops
loop
rE⋅d
rS—∫ ==−
∂rB∂t
⋅drA
Area∫
Only time derivative of B enters
loop
rE⋅d
rS—∫ =2πrE (r,t)
∂rB
∂t⋅d
rA
Area∫ = π r2 ∂Bz
∂t
Therefore: E (r,t) =−r2∂Bz
∂t
Out of page (+z)ccw
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Is Lenz’s law satisfied ????
E (r,t) =−r2∂Bz
∂t
Bz - out of page and increasing
An induced current would flow:
A ClockwiseB Counterclockwise
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What is
rE⋅d
rS
2
1
∫1
2N turns
rE⋅d
rS
2
1
∫ +rE⋅d
rS
1, wire
2
∫
=rE⋅d
rS
Loop—∫ =−Nπa2 ∂Bz
∂t
Question:
rE⋅d
rS
1, wire
2
∫ =?
Top viewA. 0 B. −
rE ⋅d
rS
2
1
∫
1
2a
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Inductance
V1 −V2 =−
rE⋅d
rS
2
1
∫ =μ0N
2πa2
ldIdt
=LdIdt
rE⋅d
rS
2
1
∫ =−Nπa2 ∂Bz
∂t
1
2Bz =μoNI
l
L =μ0N
2πa2
l Depends in geometry of coil, not I
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Inductors An inductor is a coil of wireAny length of wire has inductance: but it’s usually negligible
Engineering sign convention for labeling voltage and current
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Engineering Convention for Labeling Voltages and Currents
Two terminal deviceResistorCapacitorInductor
1. Pick one terminal and draw an arrow going in.
2. Label the current Ix.
3. Label the Voltage at that terminal Vx. This is the potential at that terminal relative to the other terminal.
Vx Ix
VR =RIR
VL =L dI L / dt
IC =C dVC / dt
No f-ing minus signs
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Power and Energy to a two terminal device
Vx Ix
Vb
At t=0 the switch is closed
Then Vx = Vb
Current Ix flows.
The power delivered to the device isP =I xVx
P =I x2R> 0
If device is a resistor
Vx =I xRIf device is an inductor
Vx =LdI x
dt
P =I xLdI x
dt=
ddt
LI x2
2⎛
⎝⎜⎞
⎠⎟
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U = d ′t P( ′t )0
t
∫ = d ′tdd ′t0
t
∫LI 2
2⎛
⎝⎜⎞
⎠⎟=
LI 2
2⎛
⎝⎜⎞
⎠⎟
P =ILdIdt
=ddt
LI 2
2⎛
⎝⎜⎞
⎠⎟Energy stored in Inductor
Where is the energy?
Consider a solenoid
Bz =μoNI
lL =
μ0N2πa2
l
LI 2
2
⎛
⎝⎜⎞
⎠⎟= πa2l( )
Bz2
2μ0
= Volume x Energy Density
Energy is stored in the magnetic field
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How much energy is stored in the magnetic field of an MRI machine?
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The potential at a is higher than the potential at b. Which of the following statements about the inductor current I could be true?
A. I is from b to a and is steady.B. I is from b to a and is increasing.C. I is from a to b and is steady.D. I is from a to b and is increasing.E. I is from a to b and is decreasing.
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A. I is from b to a and is steady.B. I is from b to a and is increasing.C. I is from a to b and is steady.D. I is from a to b and is increasing.E. I is from a to b and is decreasing.
The potential at a is higher than the potential at b. Which of the following statements about the inductor current I could be true?
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What happens to the current in the inductor after I close the switch?
VL=Vbat
What happens if I open the switch?
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Three categories of time behavior
1. Direct Current (DC) Voltages and currents are constants in time.Example: batteries - circuits driven by batteries
2. Transients Voltages and currents change in time after a switch is opened or closed. Changes diminish in time and stop if you wait long enough.
S R
LV0
VL(t)
t
VL (t) = V0 exp[- tR / L]
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R
L
V0
Consider the series connection of an inductor, a resistor and a battery. Initially no current flows through inductor and resistor. At t=0 switch is closed.What happens to current?
S
L
V0
R
VRVL
IB IRIL Notice, I’ve gone
overboard and labeled every circuit element voltage and current according to the engineering convention.
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A Word about Voltage and Current
Vx Ix
Voltage is “across”.
Current is “through”.
Voltage is the potential difference between the two terminals.
Current is the amount of charge per unit time flowing through the device.
If you catch yourself saying:
“Voltage through..”.or
“Current across…”.
You are probably confused.
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L
VB
R
VRVL
IB IRIL Kirchhoff’s voltage and current
laws.1. The sum of the currents entering any node is zero. (KCL)2. The sum of the voltages around any loop is zero. (KVL)
#1(KCL) tells usA. IB+IR+IL = 0B. IB=IR=IL C. IB=-IR, IR=IL
#2(KVL) tells usA. VB+VR+VL = 0B. VL+VR-VB=0C. VB=VR=VL
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L
VB
R
VRVL
I I Now I have cleaned things up making use of IB=-IR, IR=IL=I.
Now use device laws:VR = RIVL = L dI/dt
KVL: VL + VR - VB = 0
LdI
dt+ RI - VB = 0
This is a differential equation that determines I(t). Need an initial condition I(0)=0
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LdI (t)
dt+ RI (t)- VB = 0, I (0) = 0
This is a linear, ordinary, differential equation with constant coefficients.
Linear: only first power of unknown dependent variable and its derivatives appears. No I2, I3 etc.Ordinary: only derivatives with respect to a single independent variable - in this case t.Constant coefficients: L and R are not functions of time.
Consequence: We can solve it!
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LdI (t)
dt+ RI (t)- VB = 0, I (0) = 0
Solution:
I(t) =VBR
1- e- t /t( )
t = (L / R)
Let’s verify
This is called the “L over R” time.
Current starts at zero
Approaches a value VB/R
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What is the voltage across the resistor and the inductor?
I(t) =VBR
1- e- t /t( )
VR = RI(t) = VB 1- e- t /t( )
VL = LdI
dt= VBe
- t /t
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L
VB
R
VRVL
I I Initially I is small and VR is small.All of VB falls across the inductor, VL=VB.Inductor acts like an open circuit.
Time asymptotically I stops changing and VL is small.All of VB falls across the resistor, VR=VB. I=VB/RInductor acts like an short circuit.
![Page 75: Chapter 34: Electromagnetic Induction A time changing magnetic field induces an electric field. This electric field does not satisfy Coulombs Law](https://reader037.vdocuments.us/reader037/viewer/2022102800/56649ee85503460f94bfa0ff/html5/thumbnails/75.jpg)
Now for a Mathematical Interlude
How to solve a linear, ordinary differential equation with constant coefficients
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The L-C circuit
KCL says:A. IC=IL
B. IC+IL=0C. VL=L dIL/dt
KVL says:A. VC=VL
B. VC+VL=0C. IC=C dVL/dt
VC = VL = V
IC + IL = 0
V (t) = LdILdt
IC = CdV (t)
dt
What about initial conditions?
Must specify: IL(0) and VC(0)
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VC = VL = V
IC + IL = 0
V (t) = LdILdt
IC = CdV (t)
dt
What about initial conditions?
Must specify: IL(0) and VC(0)
dICdt
+dILdt
= 0
dICdt
= Cd 2V (t)
dt 2
dILdt
=V (t)
L
d 2V (t)
dt 2+V (t)
LC= 0
V (0) = VC (0)
IL (0) = - IC (0) = - CdV
dt t= 0
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Let’s take a special case of no current initially flowing through the inductor
d 2V (t)
dt 2+V (t)
LC= 0
V (0) = VC (0)
IL (0) = 0 = - CdV
dt t= 0
Solution
V (t) = VC (0)cos(wt)
w= 1 / LC
A:
B: V (t) = VC (0)sin(wt)
Initial charge on capacitor
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Current through Inductor and Energy Stored
Energy
UC =1
2CV 2
UL =1
2LIL
2
t
![Page 80: Chapter 34: Electromagnetic Induction A time changing magnetic field induces an electric field. This electric field does not satisfy Coulombs Law](https://reader037.vdocuments.us/reader037/viewer/2022102800/56649ee85503460f94bfa0ff/html5/thumbnails/80.jpg)
QuickTime™ and a decompressor
are needed to see this picture.