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Chapter 34. Electromagnetic Induction Electromagnetic induction is the scientific principle that underlies many modern technologies, from the generation of electricity to Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. electricity to communications and data storage. Chapter Goal: To understand and apply electromagnetic induction. 1

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Chapter 34. Electromagnetic Induction

Electromagnetic induction

is the scientific principle

that underlies many

modern technologies, from

the generation of

electricity to

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley.

electricity to

communications and data

storage.

Chapter Goal: To

understand and apply

electromagnetic induction.

1

Chapter 34. Electromagnetic Induction

Topics:

• Induced Currents

• Motional emf

• Magnetic Flux

• Lenz’s Law

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• Lenz’s Law

• Faraday’s Law

• Induced Fields

2

Chapter 34. Reading Quizzes

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Chapter 34. Reading Quizzes

3

Electromagnetic induction was

discovered by

A. Faraday.

B. Henry.

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B. Henry.

C. Maxwell.

D. Both Faraday and Henry.

E. All three.

4

Electromagnetic induction was

discovered by

A. Faraday.

B. Henry.

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B. Henry.

C. Maxwell.

D. Both Faraday and Henry.

E. All three.

5

The direction that an induced

current flows in a circuit is

given by

A. Faraday’s law.

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A. Faraday’s law.

B. Lenz’s law.

C. Henry’s law.

D. Hertz’s law.

E. Maxwell’s law.

6

The direction that an induced

current flows in a circuit is

given by

A. Faraday’s law.

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A. Faraday’s law.

B. Lenz’s law.

C. Henry’s law.

D. Hertz’s law.

E. Maxwell’s law.

7

Chapter 34. Basic Content and Examples

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Chapter 34. Basic Content and Examples

8

Faraday’s Discovery

Faraday found that there is a current in a coil

of wire if and only if the magnetic field passing

through the coil is changing. This is an informal

statement of Faraday’s law.

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statement of Faraday’s law.

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Induced Emf and Induced Current

There are a number of ways a magnetic field can be used to generate an electric current.

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It is the changing field that produces the current.

Induced Emf and Induced Current

An emf can be induced by changing thearea of a coil in a constant magnetic field

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In each example, both an emf and a current are induced because the coil is part of a complete circuit. If the circuit were open, therewould be no induced current, but there would be an induced emf.

The phenomena of producing an induced emf with the aid of amagnetic field is called electromagnetic induction.

Motional Emf

THE EMF INDUCED IN A MOVING CONDUCTOR

Each charge within the conductoris moving and experiences a magnetic force

qvBF =

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The separated charges on theends of the conductor give riseto an induced emf, called amotional emf.

Motional Emf

vBL=E

Motional emf when v, B,

and L are mutually

perpendicular

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vBL=E

Motional emf

The motional emf of a conductor of length l

moving with velocity v perpendicular to a

magnetic field B is

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EXAMPLE 34.1 Measuring the earth’s magnetic

field

QUESTION:

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EXAMPLE 34.1 Measuring the earth’s magnetic

field

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EXAMPLE 34.1 Measuring the earth’s magnetic

field

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Magnetic flux can be

defined in terms of an area vector

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Magnetic Flux

The magnetic flux measures the amount of

magnetic field passing through a loop of area A

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magnetic field passing through a loop of area A

if the loop is tilted at an angle θ from the field,

B. As a dot-product, the equation becomes:

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Lenz’s Law

There is an induced current in a closed,

conducting loop if and only if the magnetic flux

through the loop is changing. The direction of

the induced current is such that the induced

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the induced current is such that the induced

magnetic field opposes the change in the flux.

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22

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Lenz’s Law

The Emf Produced by a Moving Copper Ring.

There is a constant magnetic field directed into the page in the shaded region. The fieldis zero outside the shaded region. A copperring slides through the region.

For each of the five positions, determine whetheran induced current exists and, if so, find itsdirection.

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direction.

Tactics: Using Lenz’s Law

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Faraday’s Law

An emf is induced in a conducting loop if the

magnetic flux through the loop changes. The

magnitude of the emf is

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and the direction of the emf is such as to drive

an induced current in the direction

given by Lenz’s law.26

Problem-Solving Strategy: Electromagnetic

Induction

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Electromagnetic Waves

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Applications of Electromagnetic Induction to the Reproduction of Sound

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Transformers

A transformer is a device for increasing or decreasing an ac voltage.

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tN

∆Φ−= ssE

tN

∆Φ−= ppE

p

s

p

s

N

N=

E

E

Transformers

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s

p

s

p

p

s

N

N

V

V

I

I==

A transformer that steps up the voltage simultaneously steps

down the current, and a transformer that steps down the voltage

steps up the current.

Transformers

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Chapter 34. Summary Slides

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Chapter 34. Summary Slides

33

General Principles

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34

General Principles

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35

General Principles

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36

Important Concepts

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Important Concepts

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38

Chapter 34. Questions

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Chapter 34. Questions

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Is there an induced current in this circuit? If

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Is there an induced current in this circuit? If

so, what is its direction?

A. No

B. Yes, clockwise

C. Yes, counterclockwise

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Is there an induced current in this circuit? If

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A. No

B. Yes, clockwise

C. Yes, counterclockwise

Is there an induced current in this circuit? If

so, what is its direction?

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A square loop of copper

wire is pulled through a

region of magnetic field.

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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

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 square loop of copper

wire is pulled through a

region of magnetic field.

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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

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 current-carrying wire is pulled away from a

conducting loop in the direction shown. As the

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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 current-carrying wire is pulled away from a

conducting loop in the direction shown. As the

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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.

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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