Title :
Reduction of the Multipactor Threshold Due to Electron Cyclotron Resonance
Author :
Semenov, V.E. ; Zharova, N.A. ; Zaitsev, N.I. ; Gvozdev, A.K. ; Sorokin, A.A. ; Lisak, M. ; Rasch, J. ; Puech, J.
Author_Institution :
Inst. of Appl. Phys., Nizhny Novgorod, Russia
Abstract :
Single-surface multipactor on metal surfaces is studied in the case when the microwave electric field is superimposed on a dc electric and a permanent magnetic field. Based on a simple analysis of the electron motion, it is predicted that considerable reduction in the multipactor threshold is possible when the electron cyclotron frequency is equal to the microwave field frequency and the permanent magnetic field has the proper orientation with respect to the metal surface. The prediction is confirmed by numerical simulations, and some experimental indications of the reduced multipactor threshold are also presented.
Keywords :
high-frequency discharges; microwave switches; numerical analysis; plasma simulation; plasma switches; plasma transport processes; surface discharges; dc electric field; electron cyclotron resonance; electron motion analysis; microwave electric field; microwave field frequency; multipactor threshold reduction; numerical simulations; permanent magnetic field; single-surface multipactor; Cyclotrons; Dielectrics; Electromagnetic heating; Magnetic resonance; Metals; Microwave oscillators; Vectors; Accelerator RF Systems; avalanche breakdown; electric breakdown; magnetic fields; microwave breakdown; multipactor;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2012.2214063
