Resistive ballooning modes in an axisymmetric toroidal plasma with long mean free path

1 July 1985

journal article
Published by AIP Publishing in Physics of Fluids

Vol. 28 (7) , 2201-2208
https://doi.org/10.1063/1.865272

Abstract

Tokamak devices normally operate at such high temperatures that the resistive fluid description is inappropriate. In particular, the collision frequency may be low enough for trapped particles to exist. However, on account of the high conductivity of such plasmas, one can identify two separate scale lengths when discussing resistive ballooning modes. By describing plasma motion on one of these, the connection length, in terms of kinetic theory the dynamics of trapped particles can be incorporated. On the resistive scale length, this leads to a description in terms of modified fluid equations in which trapped particle effects appear. The resulting equations are analyzed and the presence of trapped particles is found to modify the stability properties qualitatively.

Keywords

This publication has 9 references indexed in Scilit:

Transport Effects Induced by Resistive Ballooning Modes and Comparison with High- $β_{p}$ ISX- $B$ Tokamak Confinement
Physical Review Letters, 1983
Kinetic-ballooning-mode theory in general geometry
Nuclear Fusion, 1980
High mode number stability of an axisymmetric toroidal plasma
Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1979
Resistive-Ballooning-Mode Equation
Physical Review Letters, 1978
Moment equation approach to neoclassical transport theory
Physics of Fluids, 1978
Resistive instabilities in a tokamak
Physics of Fluids, 1976
Resistive instabilities in general toroidal plasma configurations
Physics of Fluids, 1975
Effect of Field Asymmetry on Neoclassical Transport in a Tokamak
Physics of Fluids, 1972
Plasma Transport in Toroidal Confinement Systems
Physics of Fluids, 1972