The north pole of a magnet is falling towards | vedclass

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(A) According to Lenz's law,the direction of the induced current is such that it opposes the cause that produces it.As the north pole $(N)$ of the mag

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Anticlockwise

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(A) According to Lenz's law,the direction of the induced current is such that it opposes the cause that produces it.As the north pole $(N)$ of the magnet moves towards the metallic ring,the magnetic flux linked with the ring increases.To oppose this increase in magnetic flux,the upper face of the ring must behave like a north pole $(N)$ to repel the approaching magnet.$A$ face of a current-carrying loop behaves as a north pole when the current flows in an anticlockwise direction as viewed from that side.Therefore,when looked at from above,the induced current in the ring will be anticlockwise.

The north pole of a magnet is falling towards a metallic ring as shown in the figure. If looked at from above the ring,the direction of the induced current will be:

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