Betatron

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A betatron is a particle accelerator developed by Donald Kerst at the University of Illinois in 1940 to accelerate electrons. The betatron is essentially a transformer with a torus-shaped vacuum tube as its secondary coil. An alternating current in the primary coils accelerates electrons in the vacuum around a circular path. The name "betatron" (a reference to the beta particle, a fast electron) was chosen during a departmental contest. Other proposals were rheotron, inductron, and even Ausserordentlichhochgeschwindigkeitelektronenentwickelndenschwerarbeitsbeigollitron, German for "extraordinarily high-speed electron generator, hard work by golly-tron.".

The stable orbit for the electrons satisfies $\theta_0=2\pi r_0^2 H_0$ where $θ 0$ is the flux with the orbit at $r 0$ is the radius and $H 0$ is the magnetic field at $r 0$ . In other words, the magnetic field at the orbit must be half the average magnetic field over its circular cross section.

Betatrons were historically employed in particle physics experiments to provide high energy beams of electrons—up to about 300 MeV. If the electron beam is directed at a metal plate, the betatron can be used as a source of energetic x-rays or gamma rays; these x-rays may be used in industrial and medical applications (historically in radiation oncology).

Because the mass of the electron increases at relativistic speeds, the cyclotron becomes less efficient at higher energies, placing an upper limit on its beam energy. These relativistic effects are accommodated in the next generation of accelerators, the Synchrotrons.

The Radiation Center, the first private medical center to treat cancer patients with a betatron was opened by Dr. O. Arthur Stiennon, in a suburb of Madison, Wisconsin in the late 1950s^[1].