ELECTRON-BEAM CHARACTERIZATION FOR A COMPACT FAR-INFRARED FREE-ELECTRON LASER

A compact, far-infrared free-electron laser (FIR-FEL) is operating at 85 mu m at Stanford University, where the electron beam is obtained fr om a 1 1/2 cell, thermionic RF (2.856 GHz) cavity gun. This gun was no t designed for FEL operation, and under the condition at which it was intended to operate, with a peak acceleration gradient below 85 MV/m, it would not be suitable, We have explored new parameter ranges, and h ave found that at high peak gradients, from 100-140 MV/m, the gun will function satisfactorily as an FEL accelerator. For example, thirty-ni ne percent of the total gun current was transmitted through a 1% energ y window at a beam energy of gamma = 9.72. At gamma = 9.56, a 304 mA m acropulse current with an estimated rms micropulse length of 3.4 ps wa s obtained, and the normalized rms emittance was measured to be 11.6 p i-mm-mrad for the 1% energy-spread electrons, corresponding to a beam brightness of 2.3 x 10(11) A/m(2). For these parameters, the calculate d small small-signal gain for our 0.5 m-long wiggler is 110% at a wave length of 85 mu m. In this paper we characterize the electron beam fro m a 1 1/2 cell, thermionic cathode, RF cavity gun in a parameter range where it can be used as the accelerator for a far infrared FEL.