Title :
Multipactor Mitigation in Coaxial Lines by Means of Permanent Magnets
Author :
Gonzalez-Iglesias, D. ; Perez, A.M. ; Anza, S. ; Vague Cardona, J. ; Gimeno, B. ; Boria, V.E. ; Raboso, D. ; Vicente, C. ; Gil, J. ; Caspers, F. ; Conde, L.
Author_Institution :
Dept. of Appl. PhysicsInstitute of Mater. Sci., Univ. of Valencia, Valencia, Spain
Abstract :
The main aim of this paper is the analysis of the feasibility of employing permanent magnets for the multipactor mitigation in a coaxial waveguide. First, the study of a coaxial line immersed in a uniform axial magnetic field shows that multipactor can be suppressed at any RF if the external magnetic field is strong enough. Both theoretical simulations and experimental tests validate this statement. Next, multipactor breakdown of a coaxial line immersed in a hollow cylindrical permanent magnet is analyzed. Numerical simulations show that multipactor can be suppressed in a certain RF range. The performed experimental test campaign demonstrates the capability of the magnet to avoid the multipactor electron multiplication process.
Keywords :
coaxial cables; coaxial waveguides; magnetic fields; microwave switches; permanent magnets; coaxial lines; coaxial waveguide; external magnetic field; hollow cylindrical permanent magnet; multipactor electron multiplication process; multipactor mitigation; uniform axial magnetic field; Discharges (electric); Magnetic domains; Magnetic resonance; Permanent magnets; Radio frequency; Trajectory; Coaxial waveguide; RF breakdown; RF breakdown.; dc magnetic field; multipactor effect; multipactor mitigation; permanent magnet;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2361172
