1 electromagnetic induction chapter 25. 2 induction a loop of wire is connected to a sensitive...
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Electromagnetic Induction
Chapter 25
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Induction
• A loop of wire is connected to a sensitive ammeter
• When a magnet is moved toward the loop, the ammeter deflects
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Induction
• An induced current is produced by a changing magnetic field
• There is an induced emf associated with the induced current
• A current can be produced without a battery present in the circuit
• Faraday’s law of induction describes the induced emf
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Induction
• When the magnet is held stationary, there is no deflection of the ammeter
• Therefore, there is no induced current– Even though the magnet is in the loop
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Induction
• The magnet is moved away from the loop• The ammeter deflects in the opposite
direction
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Induction
• The ammeter deflects when the magnet is moving toward
or away from the loop
• The ammeter also deflects when the loop is moved
toward or away from the magnet
• Therefore, the loop detects that the magnet is moving
relative to it
– We relate this detection to a change in the magnetic field
– This is the induced current that is produced by an
induced emf
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Faraday’s law
• Faraday’s law of induction states that “the emf
induced in a circuit is directly proportional to the
time rate of change of the magnetic flux through
the circuit”
• Mathematically, ε Bd
dt
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Magnetic Flux
Definition:
• Magnetic flux is the product of the magnitude of the magnetic field and the surface area, A, perpendicular to the field
• ΦB = BA
• The field lines may make some angle θ with the perpendicular to the surface
• Then ΦB = BA cos θB
B BA B
cosB BA
normal
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Faraday’s law
• Faraday’s law of induction states that “the emf
induced in a circuit is directly proportional to the
time rate of change of the magnetic flux through
the circuit”
• Mathematically, ε Bd
dt
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Faraday’s law
• Assume a loop enclosing an area A lies in a uniform magnetic field B
• The magnetic flux through the loop is B = BA cos
• The induced emf is
• Ways of inducing emf:
• The magnitude of B can change with time
• The area A enclosed by the loop can change with time
• The angle can change with time
• Any combination of the above can occur
( cos )d BA
dt
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Motional emf
• A motional emf is the emf induced in a conductor moving through a constant magnetic field
• The electrons in the conductor experience a force,
FB = qvB that is directed along ℓ
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Motional emf
FB = qvB
• Under the influence of the force, the electrons move to the lower end of the conductor and accumulate there
• As a result, an electric field E is produced inside the conductor
• The charges accumulate at both ends of the conductor until they are in equilibrium with regard to the electric and magnetic forces
qE = qvB or E = vB
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Motional emf
E = vB
• A potential difference is maintained
between the ends of the conductor as
long as the conductor continues to move
through the uniform magnetic field
• If the direction of the motion is reversed,
the polarity of the potential difference is
also reversed
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Example: Sliding Conducting Bar
E vB
El Blv
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Example: Sliding Conducting Bar
• The induced emf is
ε Bd dx
B B vdt dt
I ε B v
R R
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Lenz’s law
• Faraday’s law indicates that the induced emf and the change in flux have opposite algebraic signs
• This has a physical interpretation that is known as Lenz’s law
• Lenz’s law: the induced current in a loop is in the direction that creates a magnetic field that opposes the change in magnetic flux through the area enclosed by the loop
• The induced current tends to keep the original magnetic flux through the circuit from changing
ε Bd
dt
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Lenz’s law
• Lenz’s law: the induced current in a loop is in the direction that creates a magnetic field that opposes the change in magnetic flux through the area enclosed by the loop
• The induced current tends to keep the original magnetic flux through the circuit from changing
ε Bd
dt
B
IIB
B increases with time
B
IIB
B decreases with time
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Example
A single-turn, circular loop of radius R is coaxial with a long solenoid of radius r and length ℓ and having N turns. The variable resistor is
changed so that the solenoid current decreases linearly from I1 to I2
in an interval Δt. Find the induced emf in the loop.
lo
NB t μ I t
2 2 Ilo
Nt πr B t μ πr t
2 2 2 1
l lo o
d t dI t I IN Nε μ πr μ πr
dt dt t
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Inductance
L is a constant of proportionality called the inductance of the coil and it depends on the geometry of the coil and other physical characteristics
The SI unit of inductance is the henry (H)
Named for Joseph Henry
IL
dε L
dtI L
AsV
1H1
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Inductor
IL
dε L
dt I L
• A circuit element that has a large self-inductance is called
an inductor
• The circuit symbol is
• We assume the self-inductance of the rest of the circuit is
negligible compared to the inductor
– However, even without a coil, a circuit will have some
self-inductance
I 1 1L I 2 2L
I I
Flux through solenoid
Flux through the loop
1 2L L
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The effect of Inductor
IL
dε L
dtI L
• The inductance results in a back emf
• Therefore, the inductor in a circuit opposes changes
in current in that circuit
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RL circuit
IL
dε L
dtI L
• An RL circuit contains an inductor and a resistor
• When the switch is closed (at time t = 0), the current begins to increase
• At the same time, a back emf is induced in the inductor that opposes the original increasing current
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Electromagnetic Waves
Chapter 25
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Plane Electromagnetic Waves
• Assume EM wave that travel in x-direction
• Then Electric and Magnetic Fields are orthogonal to x
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Plane Electromagnetic Waves
E and B vary sinusoidally with x
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Time Sequence of Electromagnetic Wave
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The EM spectrum
• Note the overlap between
different types of waves
• Visible light is a small
portion of the spectrum
• Types are distinguished
by frequency or
wavelength