What Happens when a Bar Magnet Approaches a Conducting Loop?

AI Thread Summary
When a bar magnet approaches a conducting loop, the interaction depends on the polarity of the magnet. If the magnet's north pole approaches, the loop experiences a repelling force, causing its area to increase slightly. Conversely, if the south pole approaches, the loop is attracted, leading to a slight decrease in area. The discussion emphasizes the importance of understanding electromagnetic induction principles to determine the loop's response. Clarifying these concepts is essential for accurately answering the posed question.
april_angela
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Fig.35 shows a light and flexible conducting loop X freely hung on a smooth horizontal rail. A
bar magnet PQ approaches the loop from the right. Which one of the following descriptions
about this process is correct?



A If P is a N-pole, the loop will be repelled to the left and its area will increase slightly.
B If P is a S-pole, the loop will be attracted to the right and its area will decrease slightly.
C No matter whether P is a N-pole or a S-pole, the loop will be repelled to the left and its area
will increase slightly.
D No matter whether P is a N-pole or a S-pole, the loop will be repelled to the left and its area
will decrease slightly.

can anyone help me with this qns? I've attached the diagram alrdy. I am not sure if the area will increase or decrease. and why?
 

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You should post this in the Homework section. That will ensure you get the best help for your question.
 
thanks :)
 
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