Title :
Effects of a finite axial magnetic field on the beam loading on a cavity [klystron cavity example]
Author :
Kowalczyk, Richard ; Lau, Y.Y. ; Gilgenbach, R.M.
Author_Institution :
Michigan Univ., Ann Arbor, MI, USA
Abstract :
The beam loading of a cavity is mostly computed under the assumption of an infinite axial magnetic field. In practice, a finite focusing magnetic field is almost always present. In this paper, we extend Branch´s classic paper (IEEE Trans. Electron Devices, vol.8, p.193, 1961) on ballistic bunching in that both the conductive and reactive components of the beam-loaded admittance are computed, and for general values of axial magnetic field. Also included is a comparison of the analytic formulation with a 2D particle-in-cell simulation. This work suggests that the finite axial magnetic field used in linear beam tubes (typically exceeding 1.5 times the Brillouin field) would modify the beam-loaded admittance by about 20%, or less, from that computed under the assumptions of an infinite axial magnetic field.
Keywords :
electron beam focusing; klystrons; magnetic field effects; 2D particle-in-cell simulation; Brillouin field; ballistic bunching; ballistic theory; beam-loaded admittance conductive component; beam-loaded admittance reactive component; cavity beam loading; finite axial magnetic field effects; focusing magnetic field; klystron cavity; linear beam tubes; Admittance; Analytical models; Computational modeling; Electron beams; Electron tubes; Geometry; Magnetic analysis; Magnetic fields; Magnetic susceptibility; Resonant frequency;
Conference_Titel :
Vacuum Electronics Conference, 2004. IVEC 2004. Fifth IEEE International
Print_ISBN :
0-7803-8261-7
DOI :
10.1109/IVELEC.2004.1316280
