Linear particle accelerator: Difference between revisions

[[Rolf Wideroe]] discovered Ising's paper in 1927, and as part of his PhD thesis, built an 88-inch long, two gap version of the device. Where Ising had proposed a spark gap as the voltage source, Wideroe used a [[vacuum tube]] oscillator. He successfully demonstrated that he had accelerated sodium and potassium ions to 50 keV, twice the energy they would have received if accelerated only once by the tube. By successfully accelerating a particle multiple times using the same voltage source, Wideroe demonstrated the utility of [[radio frequency]] acceleration.<ref>{{cite book |last1=Conte |first1=Mario |last2=MacKay |first2=William |title=An introduction to the physics of particle accelerators |date=2008 |publisher=World Scientific |___location=Hackensack, N.J. |isbn=9789812779601 |edition=2nd}}</ref>

This type of linac was limited by the voltage sources that were available at the time, and it was not until after [[World War II]] that [[Luis Walter Alvarez|Luis Alvarez]] was able to use newly developed high frequency oscillators to design the first resonant cavity drift tube linac. An Alvarez linac differs from the Wideroe type in that the RF power is applied to the entire [[Resonator#Cavity_resonators|resonant chamber]] through which the particle travels, and the central tubes are only used to shield the particles during the decelerating portion of the oscillator's phase. Using this approach to acceleration, meant that Alvarez's first linac was able to achieve proton energies of 31.5 MeV in 1947, the highest that had ever been reached at the time.<ref>{{cite web |title=Alvarez proton linear accelerator |url=https://www.si.edu/es/object/alvarez-proton-linear-accelerator%3Anmah_700150 |website=Smithsonian Institution |access-date=3 February 2022 |language=es}}</ref>