Answer to Question 5 (Explain
physical results)
Question 4: Use F = ma to solve for the motion of the electron
Answer to Question 4
We drop an electron of charge q = - e with zero initial speed v0 near the center of the ring at a distance y0 from the origin. The initail conditins at t=0 are as follow:
i) y[t=0] = y0 where y0<< R = radius of the ring.
ii) v[t=0] = v0 = 0 where v0 is the initial speed of the electron
1) F = m a
2) a=dv [t] / dt = dy[t] ^2 /dt = y[t]''
q=-e
3) F= q Ep = - e Ep
4) Ep = k Q y / R ^3
5) w0 = 2Pi / T= k Q e / (m R^3) = 1
Substituting equations ( 2,3,4 and 5) into 1; the differential equation for the motion of the electron through the ring at any desired time becomes
6) y[t]'' + y[t] = 0 ,
with solution
7) y[t] = y0 cos[t].
The velocity of the electron is the derivative of y[t] with respect to t or
8) y[t]' = v[t] = - y0 sin[t]
The acceleration of the electron is the derivative of the velocity with respect to t or
9) y[t]'' = a[t] = - y0 cos[t]
Equations (7, 8 and 9 ) are satisfied by the equation ( 6, i and ii )
( End of Answer to Q4 )
Answer to Question 5 (Explain
physical results)
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