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Resorting to particle-in-cell (PIC), simulation and experimental investigation, the phenomenon is observed that the starting voltage increases with the increase of input operation voltage of a magnetically insulated transmission linear oscillator (MILO). Therefore, PIC simulation and theoretical analysis are carried out for further study. The key factor responsible for the phenomenon is found, that is, the bigger the operation voltage and the bigger the rise slope of the operation voltage is, and the bigger the starting voltage is; when the rise slope of the operation voltage is infinite, the starting voltage is equal to the operation voltage. Therefore, the variation of the rise slope of the input voltage is the key factor that causes the variation of the starting spot for an MILO; when there is no change of the rise slope of the voltage, the starting spot for the same MILO will not change, and the starting voltage will not change either; when there is the increase of the rise slope of the input voltage, the starting voltage for the same MILO will increase accordingly. In addition, the expression of the self-insulating critical current for an MILO is modified partly.
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Keywords:
- magnetically insulated transmission line oscillator /
- operation voltage /
- starting voltage /
- operation curve
[1] Lemke R W, Clark M C 1987 IEEE Trans. Plasma Sci. 62 3436
[2] Clark M C, Marder B M, Bacon L D 1988 Appl. Phys. Lett. 52 78
[3] Chen D B, Fan Z K, Dong Z W, Xu Z, Zhou H J, Guo Y H, He H, Gong H T, An H S 2007 High Power Laser Part. Beams 19 820 (in Chinese) [陈代兵, 范植开, 董志伟, 许州, 周海京, 郭焱华, 何琥, 龚海涛, 安海狮 2007 强激光与粒子束 19 820]
[4] Chen D B, Fan Z K, Zhou H J, Gao F Q, He H, Guo Y H,Wang D, Wang X D, Gong H T, An H S 2007 High Power Laser and Part. Beams 19 1352 (in Chinese) [陈代兵, 范植开, 周海京, 高凤琴, 何琥, 郭焱华, 王冬, 王晓东, 龚海涛, 安海狮 2007 强激光与粒子束 19 1352]
[5] Chen D B,Wang D, Meng F B, Fan Z K 2009 IEEE Trans. Plasma Sci. 37 23
[6] Chen D B, Wang D, Meng F B, Fan Z K, Qin F, Wen J 2009 IEEE Trans. Plasma Sci. 37 1916
[7] Chen D B, Wang D, Fan Z K, Meng F B, An H S, Gong H T, Qin F 2009 Acta Phys. Sin. 58 4548 (in Chinese) [陈代兵, 王冬, 范植开, 孟凡宝, 安海狮, 龚海涛, 秦奋 2009 58 4548]
[8] Wang D, Chen D B, Fan Z K, Deng J K 2008 Acta Phys. Sin. 57 4875 (in Chinese) [王冬, 陈代兵, 范植开, 邓景康 2008 57 4875]
[9] Lemke RW, Calico S E, ClarkMC 1997 IEEE Trans. Plasma Sci. 25 364
[10] Ding W, Dong Z W, Hao J H 2006 Acta Phys. Sin. 55 4789 (in Chinese) [丁武, 董志伟, 郝建红 2006 55 4789]
[11] Fan Y W, Zhong H H, Li Z Q, Shu T, Yang H W, Yang J H, Wang Y, Luo L, Zhao Y S 2008 Chin. Phys. B 17 1804
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[1] Lemke R W, Clark M C 1987 IEEE Trans. Plasma Sci. 62 3436
[2] Clark M C, Marder B M, Bacon L D 1988 Appl. Phys. Lett. 52 78
[3] Chen D B, Fan Z K, Dong Z W, Xu Z, Zhou H J, Guo Y H, He H, Gong H T, An H S 2007 High Power Laser Part. Beams 19 820 (in Chinese) [陈代兵, 范植开, 董志伟, 许州, 周海京, 郭焱华, 何琥, 龚海涛, 安海狮 2007 强激光与粒子束 19 820]
[4] Chen D B, Fan Z K, Zhou H J, Gao F Q, He H, Guo Y H,Wang D, Wang X D, Gong H T, An H S 2007 High Power Laser and Part. Beams 19 1352 (in Chinese) [陈代兵, 范植开, 周海京, 高凤琴, 何琥, 郭焱华, 王冬, 王晓东, 龚海涛, 安海狮 2007 强激光与粒子束 19 1352]
[5] Chen D B,Wang D, Meng F B, Fan Z K 2009 IEEE Trans. Plasma Sci. 37 23
[6] Chen D B, Wang D, Meng F B, Fan Z K, Qin F, Wen J 2009 IEEE Trans. Plasma Sci. 37 1916
[7] Chen D B, Wang D, Fan Z K, Meng F B, An H S, Gong H T, Qin F 2009 Acta Phys. Sin. 58 4548 (in Chinese) [陈代兵, 王冬, 范植开, 孟凡宝, 安海狮, 龚海涛, 秦奋 2009 58 4548]
[8] Wang D, Chen D B, Fan Z K, Deng J K 2008 Acta Phys. Sin. 57 4875 (in Chinese) [王冬, 陈代兵, 范植开, 邓景康 2008 57 4875]
[9] Lemke RW, Calico S E, ClarkMC 1997 IEEE Trans. Plasma Sci. 25 364
[10] Ding W, Dong Z W, Hao J H 2006 Acta Phys. Sin. 55 4789 (in Chinese) [丁武, 董志伟, 郝建红 2006 55 4789]
[11] Fan Y W, Zhong H H, Li Z Q, Shu T, Yang H W, Yang J H, Wang Y, Luo L, Zhao Y S 2008 Chin. Phys. B 17 1804
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