Magnetic moment of an orbitting charge

AI Thread Summary
To determine the magnetic moment of a charge q rotating in a circular orbit of radius r with angular velocity w, the relevant equation is μ = I * A. The current I can be calculated by considering the charge passing through a point every 2π/w. The derived formula for the magnetic moment is μ = (q * ω * r²) / 2. This approach effectively links the concepts of charge motion and magnetic moment. Understanding the relationship between current and charge in circular motion is crucial for solving this problem.
wbrigg
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Homework Statement


"A particle of charge q is rotating in a circular orbit of radius r[/i with angular velocity w. Determine the magnetic moment associated with the motion of the charge.


Homework Equations


Q=IT?
\vec{\mu}=I\vec{A}

The Attempt at a Solution



I know how to do it, i just can't remember how to get work out the current of an orbitting charge. It's driving me insane, I know i know how to do it, i just can't remember! Please help!
 
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Remember (current) = (charge passed through)/(time elapsed).

In this case, a charge q passes through a certain point every 2pi/w.
 
yeah, that's what i was thinking. it just seemed too easy!

so

\vec{\mu} = \frac{q \omega r^{2}}{2}
 

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