1. The conducting loop in the figure is moving into the region between the magnetic poles...

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2. Is there an attractive magnetic force that tends to pull the loop in, like a magnet pulls on a paper clip? Or do you need to push the loop in against a repulsive force?

A.	You need to push the loop in against a repulsive force.
B.	There is an attractive magnetic force that tends to pull the loop in.

Solutions

Expert Solution

Concepts and reason

The concepts required to solve this problem are force on charge in magnetic field, and Lenz’s law.

Initially find the direction of force on charge carriers in the bar due to magnetic field by using right hand rule to find the direction of induced current. Finally use Lenz’s law to identify the correct statement for force.

Fundamentals

The right-hand thumb rule gives the direction of force on a charge particle. If the fingers curl from the direction of velocity to the direction of magnetic field, then the thumb points in the direction of the force exerted on the magnetic field.

Lenz’s law stats that the emf induced in a conducting material by changing magnetic flux will create a magnetic field exactly opposite to the change in the applied magnetic flux.

(1)

The magnetic field points from North to south pole that is in the upward direction and the bar is moving to the left. The fingers curl from left direction to upwards. The thumb points in into the plane of the page. So, the direction of force is into the plane. Thus, induced current is clockwise as viewed from above.

(2)

The force is required to keep the rod moving as from the Lenz’s law, the current is induced to oppose the change in magnetic flux. There is no attractive force from the magnet. The induced current in the rod results in a repulsive force in the magnetic field. Thus, you need to push the loop in against a repulsive force.

Ans: Part 1

The induced current in the circuit is in clockwise direction.

Part 2

You need to push the loop in against a repulsive force.

genius_generous answered 1 year ago

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