Question

The resistance of the loop in the figure is 0.30 Ω. a) Is the magnetic field...

The resistance of the loop in the figure is 0.30 Ω.

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a) Is the magnetic field strength increasing or decreasing?

b) At what rate \left( {\rm T/s} \right)?

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Answer #1
Concepts and reason

The concepts used to solve the problem are Ampere’s right hand rule, Faradays law of induction and Ohm’s law.

First, find the magnetic field strength by using Ampere’s right hand rule.

Finally, find the rate of change of magnetic field by comparing the Faradays law and Ohm’s law.

Fundamentals

The Ampere’s right hand rule states that, “the index finger, middle finger and the thumb are held mutually perpendicular to each other, the index finger gives the direction of current, middle finger shows the direction of magnetic field and thumb points the direction of force acting on the conducting material”.

Faraday’s law of electromagnetic induction states that, “the induced emf in any closed circuit is equal to the rate of change of magnetic flux linked in that closed circuit”.

Ohm’s law states that, “at constant temperature a steady current flows through the conductor is directly proportional to the potential difference developed in the conductor”.

The expression for the Ohm’s law is as follows:

&=IR

Here, is the electromotive force, is the current and is the resistance.

The electromotive force is the rate of change of the magnetic flux.

The expression for the Faraday’s law of induction is as follows:

op N = 3

Here, is the electromotive force, is the number of turns, is the magnetic flux and is the time.

The area of the square is as follows:

A=a?

Here, is the length and breadth of the square loop and A is the area.

The expression for the magnetic flux is as follows:

Φ = ΒΑ

Here, B is the magnetic field.

(a)

The Amperes right hand rule says that when the right hand of a person curls around the rod, the induced magnetic field due to the current in the loop points out of the page. The external magnetic field is going into the page because of that induced current that creates a magnetic field against the charge of the particle.

Therefore, the magnetic field strength increases.

(b)

The expression for the Ohm’s law is as follows:

&=IR
…… (1)

The expression for the Faraday’s law of induction is as follows:

op N = 3

Replace for and for in the above equation.

d(BA)
…… (2)

Compare equation (1) and (2).

d(BA)
=
A
dB_IR
dt
A

Replace for A in the above equation.

dB
IR
ZDP

Substitute 150 mA
for I, 0.30Ω
for R and 8.0 cm
for a to find dB/dt
.

w/10A (0.300)
(150mA) imaº
(8.0cm) ( um
100cm
(150x10-²A)(0.3052)
(8.0x10²m)
= 7.03 T/s

Ans: Part a

Thus, the external magnetic field strength will be increases.

Part b

Thus, the rate of change of magnetic field is7.03 T/s
.

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