Electromagnetic Induction, Faraday’s Experiment

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Electromagnetic Induction, Faraday’s Experiment A current can be produced by a changing magnetic field. First shown in an experiment by Michael Faraday A primary coil is connected to a battery. A secondary coil is connected to an ammeter. Section 20.1

Transcript of Electromagnetic Induction, Faraday’s Experiment

Page 1: Electromagnetic Induction, Faraday’s Experiment

Electromagnetic Induction, Faraday’s Experiment

• A current can be produced by a changing magnetic field.– First shown in an

experiment by Michael Faraday• A primary coil is connected to

a battery.

• A secondary coil is connected to an ammeter.

Section 20.1

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Faraday’s Experiment

• There is no battery in the secondary circuit.

• When the switch is closed, the ammeter reads a current and then returns to zero.

• When the switch is opened, the ammeter reads a current in the opposite direction and then returns to zero.

• When there is a steady current in the primary circuit, the ammeter reads zero.

Section 20.1

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Faraday’s Conclusions

• An electrical current is produced by a changingmagnetic field.

• The secondary circuit acts as if a source of emf were connected to it for a short time.

• It is customary to say that an induced emf is produced in the secondary circuit by the changing magnetic field because of the primary.

Section 20.1

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Magnetic Flux

• The emf is actually induced by a change in the quantity called the magnetic flux rather than simply by a change in the magnetic field.

• Magnetic flux is defined in a manner similar to that of electrical flux.

• Magnetic flux is proportional to both the strength of the magnetic field passing through the plane of a loop of wire and the area of the loop.

Section 20.1

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Magnetic Flux

• You are given a loop of wire.

• The wire is in a uniform magnetic field.

• The loop has an area A.

• The flux is defined as– ΦB = BA = B A cos θ

• θ is the angle between B and the normal to the plane

• SI unit: weber (Wb)– Wb = T . m2

Section 20.1

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Magnetic Flux

• When the field is perpendicular to the plane of the loop, as in a, θ = 0 and ΦB = ΦB, max = BA

• When the field is parallel to the plane of the loop, as in b, θ = 90° and ΦB = 0– The flux can be negative, for

example if θ = 180°

Section 20.1

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Magnetic Flux

• The flux can be visualized with respect to magnetic field lines.– The value of the magnetic flux is proportional to the total

number of lines passing through the loop.

• When the area is perpendicular to the lines, the maximum number of lines pass through the area and the flux is a maximum.

• When the area is parallel to the lines, no lines pass through the area and the flux is 0.

Section 20.1

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Electromagnetic Induction –An Experiment

• When a magnet moves toward a loop of wire, the ammeter shows the presence of a current (a).

• When the magnet is held stationary, there is no current (b).• When the magnet moves away from the loop, the ammeter shows a

current in the opposite direction (c ).• If the loop is moved instead of the magnet, a current is also detected.

Section 20.2

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Electromagnetic Induction – Results of the Experiment

• A current is set up in the circuit as long as there is relative motion between the magnet and the loop.– The same experimental results are found whether

the loop moves or the magnet moves.

• The current is called an induced currentbecause it is produced by an induced emf.

Section 20.2

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Faraday’s Law and Electromagnetic Induction

• The instantaneous emf induced in a circuit equals the negative time rate of change of magnetic flux through the circuit.

• If a circuit contains N tightly wound loops and the flux changes by ΔΦB during a time interval Δt, the average emf induced is given by Faraday’s Law:

Section 20.2

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Faraday’s Law and Lenz’ Law

• The change in the flux, ΔΦB, can be produced by a

change in B, A or θ

– Since ΦB = B A cos θ

• The negative sign in Faraday’s Law is included to indicate the polarity of the induced emf, which is found by Lenz’Law.

– The current caused by the induced emf travels in the direction that creates a magnetic field with flux opposing the change in the original flux through the circuit.

Section 20.2

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Problem

A coil has 50 turns and dimension 2cmx3cm.Assume each turn has the same area and thetotal resistance of the coil is 0.5Ω. A magneticfield is applied perpendicular to the plane of thecoil and changes from 0.00 T to 0.1 T in 1.5seconds (a) Find the induced emf when the fieldis changing (b) What is the magnitude of theinduced current?

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Lenz’ Law – Example

• The magnetic field, , becomes smaller with time.

– This reduces the flux.

• The induced current will produce an induced field,

, in the same direction as the original field.

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Application of Faraday’s Law – Motional emf

• A straight conductor of length ℓ moves perpendicularly with constant velocity through a uniform field.

• The electrons in the conductor experience a magnetic force.– F = q v B

• The electrons tend to move to the lower end of the conductor.

Section 20.3

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Motional emf

• As the negative charges accumulate at the base, a net positive charge exists at the upper end of the conductor.

• As a result of this charge separation, an electric field is produced in the conductor.

• Charges build up at the ends of the conductor until the downward magnetic force is balanced by the upward electric force.

• There is a potential difference between the upper and lower ends of the conductor.

Section 20.3

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Motional emf, Cont.

• The potential difference between the ends of the conductor can be found by– ΔV = E l = B ℓ v

– The upper end is at a higher potential than the lower end

• A potential difference is maintained across the conductor as long as there is motion through the field.– If the motion is reversed, the polarity of the potential

difference is also reversed.

Section 20.3

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Problem

A bar magnet 0.5 m long is sliding in a uniform magnetic filed of0.5 T at a rate of 2.5m/s. (a) find the induced emf in the movingrod (b) Find current flowing through the circuit if the resistance if5Ω (c) What is the magnitude of the magnetic force on the barand the power delivered to the resistor.

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Motional emf in a Circuit

• Assume the moving bar has zero resistance.

• As the bar is pulled to the right with a given velocity under the influence of an applied force, the free charges experience a magnetic force along the length of the bar.

• This force sets up an induced current because the charges are free to move in the closed path.

Section 20.3

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Motional emf in a Circuit, Cont.

• The changing magnetic flux through the loop and the corresponding induced emf in the bar result from the change in area of the loop.

• The induced, motional, emf acts like a battery in the circuit.

Section 20.3

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Generators

• Alternating Current (AC) generator

– Converts mechanical energy to electrical energy

– Consists of a wire loop rotated by some external means

– There are a variety of sources that can supply the energy to rotate the loop.

• These may include falling water, heat by burning coal to produce steam

Section 20.4

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AC Generators, Cont.

• Basic operation of the generator– As the loop rotates, the

magnetic flux through it changes with time.

– This induces an emf and a current in the external circuit.

– The ends of the loop are connected to slip rings that rotate with the loop.

– Connections to the external circuit are made by stationary brushes in contact with the slip rings.

Section 20.4

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AC Generators, Final

• The emf generated by the rotating loop can be found by

ε =2 B ℓ v=2 B ℓ sin θ

• If the loop rotates with a constant angular speed, ω, and N turns

ε = N B A ω sin ω t

• ε = εmax when loop is parallel to the field

• ε = 0 when the loop is perpendicular to the field

Section 20.4

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Problem

Find the maximum induced emf of a generator with aconducting loop of length 20cm having 100 turns is rotatedwith a constant angular velocity of 2 rad/s in a uniform filed B =0.1 T.

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AC Generators – Detail of Rotating Loop

• The magnetic force on the charges in the wires AB and CD is perpendicular to the length of the wires.

• An emf is generated in wires BC and AD.

• The emf produced in each of these wires is ε= B ℓ v= B ℓ sin θSection 20.4

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Motors

• Motors are devices that convert electrical energy into mechanical energy.

– A motor is a generator run in reverse.

• A motor can perform useful mechanical work when a shaft connected to its rotating coil is attached to some external device.

Section 20.4

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Motors and Back emf

• The phrase back emf is used for an emf that tends to reduce the applied current.

• When a motor is turned on, there is no back emf initially.

• The current is very large because it is limited only by the resistance of the coil.

Section 20.4

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Motors and Back emf, Cont.

• As the coil begins to rotate, the induced back emf opposes the applied voltage.

• The current in the coil is reduced.

• The power requirements for starting a motor and for running it under heavy loads are greater than those for running the motor under average loads.

Section 20.4

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Self-inductance

• Self-inductance occurs when the changing flux through a circuit arises from the circuit itself.– As the current increases, the magnetic flux through a

loop due to this current also increases.

– The increasing flux induces an emf that opposes the change in magnetic flux.

– As the magnitude of the current increases, the rate of increase lessens and the induced emf decreases.

– This decreasing emf results in a gradual increase of the current.

Section 20.5

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Self-inductance, Cont.

• The self-induced emf must be proportional to the time rate of change of the current.

– L is a proportionality constant called the inductance of the device.

– The negative sign indicates that a changing current induces an emf in opposition to that change.

Section 20.5

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Self-inductance, Final

• The inductance of a coil depends on geometric factors.

• The SI unit of self-inductance is the Henry

– 1 H = 1 (V · s) / A

• You can determine an expression for L

Section 20.5

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Inductor in a Circuit

• Inductance can be interpreted as a measure of opposition to the rate of change in the current.– Remember resistance R is a measure of opposition to the

current.

• As a circuit is completed, the current begins to increase, but the inductor produces an emf that opposes the increasing current.– Therefore, the current doesn’t change from 0 to its

maximum instantaneously.

Section 20.6

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RL Circuit

• When the current reaches its maximum, the rate of change and the back emf are zero.

• The time constant, , for an RL circuit is the time required for the current in the circuit to reach 63.2% of its final value.

Section 20.6

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RL Circuit, Graph

• The current increases toward the maximum value of ε/R

Section 20.6

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RL Circuit, Cont.

• The time constant depends on R and L.

• The current at any time can be found by

Section 20.6

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Energy Stored in a Magnetic Field

• The emf induced by an inductor prevents a battery from establishing an instantaneous current in a circuit.

• The battery has to do work to produce a current.

– This work can be thought of as energy stored by the inductor in its magnetic field.

– PEL = ½ L I2

Section 20.7

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AC Circuits and Circuit Theory

– Resistor

– Capacitor

– Inductor

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Electromagnetic Waves

• Electromagnetic waves are composed of fluctuating electric and magnetic fields.

• Electromagnetic waves come in various forms.

– These forms include

• Visible light

• Infrared

• Radio

• X-rays

Introduction

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AC Circuit

• An AC circuit consists of a combination of circuit elements and an AC generator or source.

• The output of an AC generator is sinusoidal and varies with time according to the following equation– Δv = ΔVmax sin 2ƒt

• Δv is the instantaneous voltage

• ΔVmax is the maximum voltage of the generator

• ƒ is the frequency at which the voltage changes, in Hz

Section 21.1

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Resistor in an AC Circuit

• Consider a circuit consisting of an AC source and a resistor.

Section 21.1

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Resistor, Cont.

• The graph shows the current through and the voltage across the resistor.

• The current and the voltage reach their maximum values at the same time.

• The current and the voltage are said to be in phase.

Section 21.1

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More About Resistors in an AC Circuit

• The direction of the current has no effect on the behavior of the resistor.

• The rate at which electrical energy is dissipated in the circuit is given by– P = i² R

• Where i is the instantaneous current

• The heating effect produced by an AC current with a maximum value of Imax is not the same as that of a DC current of the same value.

• The maximum current occurs for a small amount of time.

Section 21.1

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rms Current and Voltage

• The rms current is the direct current that would dissipate the same amount of energy in a resistor as is actually dissipated by the AC current.

• Alternating voltages can also be discussed in terms of rms values.

Section 21.1

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rms Graph

• The average value of i² is ½ I²maxSection 21.1

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Power Revisited

• The average power dissipated in resistor in an AC circuit carrying a current I is

– Pav = I²max R

Section 21.1