Flow impedance in a uniform magnetically insulated transmission line

被引:13
|
作者
Mendel, CW
Seidel, DB
机构
[1] Sandia Natl Labs, Albuquerque, NM 87185 USA
[2] Cove Consulting, Albuquerque, NM 87110 USA
来源
PHYSICS OF PLASMAS | 1999年 / 6卷 / 12期
关键词
D O I
10.1063/1.873770
中图分类号
O35 [流体力学]; O53 [等离子体物理学];
学科分类号
070204 ; 080103 ; 080704 ;
摘要
In two recent publications [C. W. Mendel, Jr. and S. E. Rosenthal, Phys. of Plasmas 2, 1332 (1995), C. W. Mendel, Jr. and S. E. Rosenthal, Phys. of Plasmas 3, 4207 (1996)] relativistic electron flow in cylindrical magnetically insulated transmission lines was analyzed and modeled under the assumption of negligible electron pressure. The model allows power flow in these lines to be accurately calculated under most conditions. The model was developed for coaxial right circular cylindrical electrodes. It is shown here that the model applies equally well to arbitrary cylindrical systems, i.e., systems consisting of electrodes of arbitrary cross section. (C) 1999 American Institute of Physics. [S1070-664X(99)03712-X].
引用
收藏
页码:4791 / 4793
页数:3
相关论文
共 50 条
  • [1] Generalized Model for Magnetically Insulated Transmission Line Flow
    Ottinger, Paul F.
    Schumer, Joseph W.
    Hinshelwood, David D.
    Allen, Raymond J.
    IEEE TRANSACTIONS ON PLASMA SCIENCE, 2008, 36 (05) : 2708 - 2721
  • [2] Modeling dynamic magnetically insulated transmission line flow in a transmission line code
    Schumer, J. W.
    Ottinger, P. F.
    Hinshelwood, D. D.
    Allen, R. J.
    2007 IEEE PULSED POWER CONFERENCE, VOLS 1-4, 2007, : 802 - 806
  • [3] Effect on electron flow of impedance change in magnetically insulated transmission lines
    Liu, Laqun
    Liu, Dagang
    Wang, Xueqiong
    Wang, Huihui
    Qiangjiguang Yu Lizishu/High Power Laser and Particle Beams, 2012, 24 (09): : 2255 - 2258
  • [4] Investigation of a high impedance magnetically insulated transmission line oscillator with hollow load
    Zhou, Heng
    Shu, Ting
    Li, Zhi-qiang
    PHYSICS OF PLASMAS, 2012, 19 (09)
  • [5] An Iterative Method to Determine the Vacuum Impedance of Magnetically Insulated Transmission Line System
    Gong, Zhenzhou
    Wei, Hao
    Fan, Siyuan
    Sun, Fengju
    Qiu, Aici
    IEEE TRANSACTIONS ON PLASMA SCIENCE, 2022, 50 (12) : 4927 - 4932
  • [6] Effects of Electron Flow Current Density on Flow Impedance of Magnetically Insulated Transmission Lines
    He Yong
    Zou Wen-Kang
    Song Sheng-Yi
    CHINESE PHYSICS LETTERS, 2011, 28 (08)
  • [7] Explicit Brillouin Flow Solutions in Magnetrons, Magnetically Insulated Line Oscillators, and Radial Magnetically Insulated Transmission Lines
    Lau, Y. Y.
    Packard, Drew A.
    Swenson, Christopher J.
    Luginsland, John W.
    Li, Dion
    Jassem, Abhijit
    Jordan, Nicholas M.
    McBride, Ryan D.
    Gilgenbach, Ronald M.
    IEEE TRANSACTIONS ON PLASMA SCIENCE, 2021, 49 (11) : 3418 - 3437
  • [8] Analytic model of a magnetically insulated transmission line with collisional flow electrons
    Stygar, W. A.
    Wagoner, T. C.
    Ives, H. C.
    Corcoran, P. A.
    Cuneo, M. E.
    Douglas, J. W.
    Gilliland, T. L.
    Mazarakis, M. G.
    Ramirez, J. J.
    Seamen, J. F.
    Seidel, D. B.
    Spielman, R. B.
    PHYSICAL REVIEW SPECIAL TOPICS-ACCELERATORS AND BEAMS, 2006, 9 (09):
  • [9] A tunable magnetically insulated transmission line oscillator
    樊玉伟
    王晓玉
    赫亮
    钟辉煌
    张建德
    Chinese Physics B, 2015, 24 (03) : 259 - 262
  • [10] MAGNETICALLY INSULATED TRANSMISSION-LINE OSCILLATOR
    CLARK, MC
    MARDER, BM
    BACON, LD
    APPLIED PHYSICS LETTERS, 1988, 52 (01) : 78 - 80
12345