Title :
Improved electrostatic design for MILO cathodes
Author :
Haworth, Michael D. ; Cartwright, Keith L. ; Luginsland, John W. ; Shiffler, Donald A. ; Umstattd, Ryan J.
Author_Institution :
Air Force Res. Lab., Kirtland AFB, NM, USA
fDate :
6/1/2002 12:00:00 AM
Abstract :
Recent experimental and computer simulation results on a magnetically insulated transmission line oscillator (MILO) have indicated that the large beam-current density emitted from each end of the cathode leads to anode plasma formation. This initiates bipolar space-charge flow in the anode-cathode gap that severely perturbs the electron flow at the launch point. The result is significant microwave power reduction on a 600-ns time scale. The field-shaper cathode, used previously to extend the MILO RF pulse duration beyond 400 ns, is shown to have several deficiencies concerning anode plasma formation. We report on implementation of miniature Pierce focusing electrodes on each end of the MILO cathode as a way to control the beam current density, and hence, to minimize anode plasma.
Keywords :
cathodes; current density; digital simulation; electron beam focusing; electrostatic lenses; impact ionisation; microwave oscillators; microwave tubes; space charge; MILO cathodes; RF pulse duration; anode plasma formation; anode plasma minimisation; beam current density control; beam-current density; bipolar space-charge flow initiation; computer simulation; electron flow; electrostatic design; field-shaper cathode; magnetically insulated transmission line oscillator; microwave power reduction; miniature Pierce focusing electrodes; time scale; Anodes; Cathodes; Computer simulation; Electrons; Electrostatics; Insulation; Microwave oscillators; Plasma density; Plasma simulation; Power transmission lines;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2002.801550
