A relativistic magnetron priming technique using multiple cathodes is simulated with a three-dimensional, fully electromagnetic, particle-in-cell code. This technique is based on electron emission from N2 individual cathodes in an N-cavity magnetron to prime the π mode. In the case of the six-cavity relativistic magnetron, π-mode start-oscillation times are reduced up to a factor of 4, and mode competition is suppressed. Most significantly, the highest microwave field power is observed by utilizing three cathodes compared to other recently explored priming techniques.

Topics
Cavity magnetrons, Magnetic fields, Radiation therapy equipment, RADAR, Radiowave and microwave technology, Signal processing, Laser physics, Particle-in-cell method, Plasma sources, Plasma acceleration
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© 2005 American Institute of Physics.
2005
American Institute of Physics
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