lin qi wen, wang wen dou, xie wei ping, et al. Transverse spacecharge flow in magnetically insulated conical transmission lines[J]. High Power Laser and Particle Beams, 2003, 15.
Citation:
lin qi wen, wang wen dou, xie wei ping, et al. Transverse spacecharge flow in magnetically insulated conical transmission lines[J]. High Power Laser and Particle Beams, 2003, 15.
lin qi wen, wang wen dou, xie wei ping, et al. Transverse spacecharge flow in magnetically insulated conical transmission lines[J]. High Power Laser and Particle Beams, 2003, 15.
Citation:
lin qi wen, wang wen dou, xie wei ping, et al. Transverse spacecharge flow in magnetically insulated conical transmission lines[J]. High Power Laser and Particle Beams, 2003, 15.
Electromagnetic field theory and electron motion conservation equations are used to derive numerical model of transverse spacecharge flow and magnetically insulated critical condition in conical transmission lines. Through numerical calculation, we have discussed the influence of the voltage and the cone's geometrical parameters on the transverse spacecharge flow and magnetically insulated performances. The higher the voltage is, the larger the spacecharge flow without magnetic field, and the better magnetically insutated performances. The geometrical factor K in the three geometrical parameters of the lines has the greatest influence on the transmission performances.
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