- #1
DarkWarrior
- 5
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Hello, I'm stuck (again) on a physics problem.
The problem:
Early in 1981 the Francis Bitter National Magnet Laboratory at M.I.T. commenced operation of a 3.3 cm diameter cylindrical magnet, which produces a 30 T field, then the world's largest steady-state field. The field magnitude can be varied sinusoidally between the limits of 29.6 and 30.9 T at a frequency of 15 Hz. When this is done, what is the maximum value of the magnitude of the induced electric field at a radial distance of 1.6 cm from the axis?
What I've done so far: I've used Faraday's law, and after messing around with the equation I got E = (r/2)(dB/dt). As I understand it, the induced electric field is inside the magnetic field (r is less than R), so I thought this equation was correct.
R= .0165 m
r = .016 m
dB/dt = 19.5 Tesla/second. Since the frequency is 15, you multiply the difference of 30.9 and 29.6 by 15, getting 19.5
However when I plug the numbers in, my answer comes out wrong. Can someone point out where I screwed up? Thank you!
The problem:
Early in 1981 the Francis Bitter National Magnet Laboratory at M.I.T. commenced operation of a 3.3 cm diameter cylindrical magnet, which produces a 30 T field, then the world's largest steady-state field. The field magnitude can be varied sinusoidally between the limits of 29.6 and 30.9 T at a frequency of 15 Hz. When this is done, what is the maximum value of the magnitude of the induced electric field at a radial distance of 1.6 cm from the axis?
What I've done so far: I've used Faraday's law, and after messing around with the equation I got E = (r/2)(dB/dt). As I understand it, the induced electric field is inside the magnetic field (r is less than R), so I thought this equation was correct.
R= .0165 m
r = .016 m
dB/dt = 19.5 Tesla/second. Since the frequency is 15, you multiply the difference of 30.9 and 29.6 by 15, getting 19.5
However when I plug the numbers in, my answer comes out wrong. Can someone point out where I screwed up? Thank you!