PHYA22H3 Chapter 34: PHYA22 Chapter 34.doc

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coralyak541

17 Apr 2012

School

UTSC

Department

Physics and Astrophysics

Course

PHYA22H3

Professor

Brian Wilson

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PHYA22H3 Full Course Notes

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Document Summary

There is no current if the field through the coil is not changing so it"s not the magnetic field itself that is responsible for the current but the changing magnetic field. Induced current: the current in a circuit due to a changing magnetic field (not caused by a battery). Motional emf: an induced current can be created by two different ways, by changing the size or orientation of a circuit in a stationary magnetic, by changing the magnetic field through a stationary circuit. field. The magnetic force on the charge carriers in a moving conductor creates an electric field e = vb inside the conductor. The motion of the wire through a magnetic field induces a potential difference. I = vlb/r, where r is the total resistance. There is no magnetic force on a charge moving parallel to a magnetic field. Force required to pull the wire with a constant speed v: fpull = fmag = ilb = vl2b2/r.

Related Questions

1a) Faraday discovered that a current is induced in a coil

A) only when the N pole of a magnet is inside the coil
B) only when the S pole of a magnet is inside the coil
C) only when there is a magnetic field inside the coil
D) only when the magnetic field inside the coil is changing

1b). A conductor moves through a uniform magnetic field at speed v and has a motional emf V created across it. If the conductor were to move twice as fast through the magnetic field, the motional emf would be:

A) V
B) 2V
C) 4V
D) V/2
E) V/4

1c) In the conducting rail discussed in section 25.2 (where the rail is moving at constant speed), what can you say about the power input due to the person pulling on the rail and the power dissipated in the resistance?

A) Power input from pull = power dissipated in R
B) Power input from pull > power dissipated in R
C) Power input from pull < power dissipated in R

1d) The electric generator as shown in the reading generates electricity by:

A) rotating a loop inside a magnetic field
B) moving a magnet in and out of a loop
C) sliding a loop over a magnet
D) running current through a loop in a magnetic field

1e) The magnetic flux through a loop:

A) is proportional to the number of magnetic field lines going through it
B) depends just on the B field going through the loop
C) is maximized when the B field lines in the plane of the loop
D) is zero when the B field is perpendicular to the plane of the loop
E) doesn't depend on the direction of the B field

1f) According to Lenz's Law, the induced B field (due to the induced current) will:

A) be in the opposite direction of the existing B field
B) be in the same direction as the existing B field
C) be in the same direction as the change in the existing B field
D) be in the opposite direction of the change in the existing B field

1g) A stationary coil experiences a doubling of its magnetic field (no change in direction of the field) in a time T and has a given induced EMF. If the same change were to have happened in half the time (T/2), the induced EMF would have been:

A) half as large
B) the same
C) twice as large
D) one-fourth as large
E) four times as large

1h) Eddy currents:

A) make it hard to pull a nonmagnetic material through a magnetic field
B) make it hard to pull a magnetic material through a magnetic field
C) speed up a magnetic material moving through a magnetic field
D) speed up a nonmagnetic material moving through a magnetic field