cmb323 said:
The ring is far from the ends of the solenoid, and I agree that there is a changing flux enclosed by the ring. The problem (in a famous textbook) that caused me to question the validity of the emf equation had r = 0.01 m and R = 0.02 m. Since r is close to R perhaps a simplifying assumption that is not stated or just an erroneous use of the formula?
If R is increased to 1 km, then the equation (does not include R) gives the same induced emf – this fails any test of reasonableness.
I think that the solution for emf induced in the ring is above my pay grade and requires the use of magnetic vector potential. A possible equation along these lines has R in the denominator, thereby passing a test of reasonableness.
What equation would that be?
No, it's not 'above your pay grade' and no it does not require magnetic vector potential. So cheer up!
Ok, to review: I am assuming the ring is (1) coaxial with the solenoid and (2) it is located somewhere near the middle of the solenoid lengthwise or at least not very close to either end.
Bearing this in mind, I know that it sounds incredible that the induced emf is the same irrespective of the diameter of the ring, but such is the case and it can easily be proven by one of Maxwell's equations together with the Stokes theorem. The line integral of the E field of a given arc length will be smaller the larger R is. But the line integral of E around the entire ring will still be the same irrespective of the size of R.
I do want to mention one caveat: Faraday says that emf = - ∂φ/∂t but it must be appreciated that φ is the TOTAL flux including any set up by the current-carrying ring itself. So in empty space it's exact but with finite current in the ring the total emf changes to - (∂φ
e/∂t - ∂φ
r/∂t) with φ
e the externally applied flux (i.e. the solenoid in your case) and φ
r the flux set up by the current-carrying ring. Usually it's assumed that the current is small enough so the second term can be ignored.
And even that statement is approximate. The complete solution must include the ring-induced flux modifying the solenoid flux, since ring flux couples into the solenoid just as solenoid flux couples into the ring. But we won't go there this time.