Alfvén-wave heating in resistive MHD
- 1 August 1989
- journal article
- research article
- Published by Cambridge University Press (CUP) in Journal of Plasma Physics
- Vol. 42 (1) , 27-58
- https://doi.org/10.1017/s0022377800014173
Abstract
Resonant absorption of Alfvén waves in tokamak plasmas is studied numerically using the linearized equations of resistive magnetohydrodynamics. A numerical code based on a finite-element discretization is used for determining the stationary state of a cylindrical plasma column that is excited by an external periodic driver. The energy dissipation rate in the stationary state is calculated and the dependence of the plasma heating on electrical resistivity, the equilibrium profiles, and the wavenumbers and frequency of the external driver is investigated. Resonant absorption is extremely efficient when the plasma is excited with a frequency near that of a so-called ‘collective mode’. The heating of a plasma by driving it at the frequencies of discrete Alfvén waves is also investigated.Keywords
This publication has 25 references indexed in Scilit:
- Alfvén wave heating of a cylindrical plasma using axisymmetric waves. Part 2. Kinetic theoryJournal of Plasma Physics, 1986
- Computing The Complex Eigenvalue Spectrum for Resistive MagnetohydrodynamicsNorth-Holland Mathematics Studies, 1986
- Computing complex eigenvalues of large non-Hermitian matricesComputer Physics Communications, 1985
- Normal mode analysis for resistive cylindrical plasmasComputer Physics Communications, 1985
- Resistive effects on Alfvén wave heatingJournal of Plasma Physics, 1977
- Approximation of the spectrum of a non-compact operator given by the magnetohydrodynamic stability of a plasmaNumerische Mathematik, 1977
- A new finite element approach to the normal mode analysis in magnetohydrodynamicsJournal of Computational Physics, 1975
- Decay of MHD waves by phase mixingThe European Physical Journal A, 1973
- Decay of MHD waves by phase mixingThe European Physical Journal A, 1973
- Electrostatic oscillations in cold inhomogeneous plasma I. Differential equation approachJournal of Plasma Physics, 1971