Magnetic force on a charge carrying wire

AI Thread Summary
A current-carrying wire in a magnetic field will experience a magnetic force that affects the weight measured on a scale. When the current flows, it creates an upward magnetic force, causing the magnet to weigh less due to Newton's Third Law, which states that every action has an equal and opposite reaction. The Right Hand Rule helps visualize this, indicating the direction of the magnetic force relative to the current. If the wire pushes the magnet upward, the magnet simultaneously pushes down on the wire, increasing its apparent weight. The discussion also raises a scenario about the effects of a rotating setup with a broad magnet and continuous current flow.
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[SOLVED] Magnetic force on a charge carrying wire

Homework Statement



A current carrying wire is in a magnetic field as shown below. The magnet is on a scale. Given this setup, does the scale read more or less weight? Explain using the Right Hand Rule and Newton's Third Law. Note: The apparatus depicted is a magnet sitting on the mass pan of a balance.

Homework Equations



The RH rule is a bit long to explain here.. basically, the current is flowing W, and the magnetic force is N to S.

Newton's 3rd: For every action, there is an equal and opposite reaction.

The Attempt at a Solution



The wire is carrying current, but the current is not given. Current must be positive, so therefore it has a charge of >0. Positive current exerts a force upward based on the drawing, so the magnet will weigh less. I don't know how to explain this in terms of the RH rule, though. My best guess:

With my thumb pointing in the direction of the current and fingers wrapped around the wire, the magnetic force flows N to S. My open palm would face left? right? up? down?, which corresponds to the force the magnet will feel. Because of Newton's Third Law, the weight will _____.
 

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So if the magnetic force on the wire is upward, then the magnet itself will push downward, resulting in a weight gain.

Right?

Thanks for the links, also. Much more informative than my prof's lecture notes.
 
Right. If the magnet pushes the wire up, the wire pushes the magnet down--increasing its apparent weight.
 
Awesome. Thanks for the help!
 


Doc Al said:
Right. If the magnet pushes the wire up, the wire pushes the magnet down--increasing its apparent weight.

Hmm... What if a wire is attached to the N surface of a very broad magnet? Now if the current is switched on, and the whole setup is free to rotate on a wheel, what will happen? Will the BIL force continue to rotate the wire with the magnet for as long as the current flows?
 

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