NEW TERMS IN MHD EQUATIONS AND THEIR IMPLICATIONS FOR THE INERTIAL CONFINEMENT FUSION CONCEPT.

被引:0
|
作者
Auluck, S.K.H. [1 ]
机构
[1] BARC, Bombay, India, BARC, Bombay, India
来源
Journal of Plasma Physics | 1986年 / 36卷 / pt 2期
关键词
EQUATIONS OF MOTION - MAGNETIC FIELDS - NUCLEAR REACTORS; FUSION; -; PLASMAS; Confinement;
D O I
暂无
中图分类号
学科分类号
摘要
The MHD equations are rederived without neglecting the electron inertia and new terms are obtained. The revised equations predict that strong magnetic fields are spontaneously generated even in an ideally symmetric ICF implosion in contrast to the conventional theory where an ideal ICF implosion is considered to be free of magnetic fields. The complexity of the implosion problem is illustrated with reference to cylindrical and spherical geometries. The existence of this effect has been verified in the case of a Z-pinch. Experiments can be devised to detect it in existing ICF installations. It is suggested that scientific breakeven may be achieved using existing installations if the targets are optimized in accordance with the present theory.
引用
收藏
页码:211 / 234
相关论文
共 50 条
  • [41] A new regularity criterion for weak solutions to the viscous MHD equations in terms of the vorticity field
    Zhou, Yong
    Gala, Sadek
    NONLINEAR ANALYSIS-THEORY METHODS & APPLICATIONS, 2010, 72 (9-10) : 3643 - 3648
  • [42] Inertial confinement fusion program at lawrence livermore national laboratory: The National Ignition Facility, inertial fusion energy, 100-1000 TW lasers, and the fast igniter concept
    Lowdermilk, WH
    JOURNAL OF NONLINEAR OPTICAL PHYSICS & MATERIALS, 1997, 6 (04): : 507 - 533
  • [43] Shock Ignition: A New Approach to High Gain Inertial Confinement Fusion on the National Ignition Facility
    Perkins, L. J.
    Betti, R.
    LaFortune, K. N.
    Williams, W. H.
    PHYSICAL REVIEW LETTERS, 2009, 103 (04)
  • [44] Numerical simulation on a new cylindrical target for Z-pinch driven inertial confinement fusion
    Chu, Y. Y.
    Wang, Z.
    Qi, J. M.
    Wu, F. Y.
    Li, Z. H.
    NUCLEAR FUSION, 2017, 57 (06)
  • [45] New aspects for fusion energy using inertial confinement (vol 25, pg 37, 2007)
    Hora, H.
    LASER AND PARTICLE BEAMS, 2007, 25 (02) : 327 - 327
  • [46] Study of fusion regimes in an inertial electrostatic confinement device using the new eclipse disk diagnostic
    Murali, S. Krupakar
    Cipiti, B. B.
    Santarius, J. F.
    Kulcinski, G. L.
    PHYSICS OF PLASMAS, 2006, 13 (05)
  • [47] Development and characterization of a Z-pinch-driven hohlraum high-yield inertial confinement fusion target concept
    Cuneo, ME
    Vesey, RA
    Porter, JL
    Chandler, GA
    Fehl, DL
    Gilliland, TL
    Hanson, DL
    McGurn, JS
    Reynolds, PG
    Ruggles, LE
    Seamen, H
    Spielman, RB
    Struve, KW
    Stygar, WA
    Simpson, WW
    Torres, JA
    Wenger, DF
    Hammer, JH
    Rambo, PW
    Peterson, DL
    Idzorek, GC
    PHYSICS OF PLASMAS, 2001, 8 (05) : 2257 - 2267
  • [48] Unified first-principles equations of state of deuterium-tritium mixtures in the global inertial confinement fusion region
    Dongdong Kang
    Yong Hou
    Qiyu Zeng
    Jiayu Dai
    Matter and Radiation at Extremes, 2020, 5 (05) : 63 - 72
  • [49] Unified first-principles equations of state of deuterium-tritium mixtures in the global inertial confinement fusion region
    Kang, Dongdong
    Hou, Yong
    Zeng, Qiyu
    Dai, Jiayu
    MATTER AND RADIATION AT EXTREMES, 2020, 5 (05)
  • [50] A new time and space resolved transmission spectrometer for research in inertial confinement fusion and radiation source development
    Knapp, P. F.
    Ball, C.
    Austin, K.
    Hansen, S. B.
    Kernaghan, M. D.
    Lake, P. W.
    Ampleford, D. J.
    McPherson, L. A.
    Sandoval, D.
    Gard, P.
    Wu, M.
    Bourdon, C.
    Rochau, G. A.
    McBride, R. D.
    Sinars, D. B.
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2017, 88 (01):
12345