In a betatron the magnetic flux across an equilibrium orbit of radius `r = 25 cm` grows during the acceleration time at paractically constant rate `Phi = 5.0 Wb//s`. In the process, the electrons acquire an energy `W = 25 MeV`. Find the number of revolutions made by the electron during the acedeleration time and the corresponding distance covered by it.

In a betatron the magnetic flux across an equilibrium orbit of radius

1.	In a betatron the magnetic flux across an equilibrium orbit of radius `r = 25 cm` grows during the acceleration time at paractically constant rate `Phi = 5.0 Wb//s`. In the process, the electrons acquire an energy `W = 25 MeV`. Find the number of revolutions made by the electron during the acedeleration time and the corresponding distance covered by it.
Answer» The increment is energy per revoltion is `e Phi`, so the number of revoltutions is, `N = (W)/(e Phi)` The distance traversed is, `s = 2pi rN`

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