Electromagnetic wave propagation in relativistic magnetized plasmas

doi:10.1016/0021-9991(85)90072-5

Journal of Computational Physics

Volume 61, Issue 3, December 1985, Pages 403-416

https://doi.org/10.1016/0021-9991(85)90072-5 Get rights and content

Abstract

An improved mathematical technique and a new code for deriving the conductivity tensor for collisionless plasmas have been developed. The method is applicable to a very general case, including both hot (relativistic) and cold magnetized plasmas, with only isotropic equilibrium distributions being considered here. The usual derivation starts from the relativistic Vlasov equation and leads to an integration over an infinite sum of Bessel functions which has to be done numerically. In the new solution the integration is carried out over a product of two Bessel functions only. This reduces the computing time very significantly. An added advantage over existing codes is our capability to perform the computations for waves propagating obliquely to the magnetic field. Both improvements greatly facilitate investigations of properties of the plasma under conditions hitherto unexplored.

References (11)

N.A. Krall et al.
Principles of Plasma Physics
(1973)
T.H. Stix
The Theory of Plasma Waves
(1962)
A.G. Sitenko et al.
Sov. Phys. JETP
(1957)
I.P. Shkarofsky
Phys. Fluids
(1966)
K. Imre, private...

There are more references available in the full text version of this article.

Cited by (10)

A microinstability code for a uniform magnetized plasma with an arbitrary distribution function
1992, Journal of Computational Physics
We have developed a very general computer code for studying microinstabilities in a uniform magnetized plasma. Employing a new algorithm to perform two-dimensional numerical integrals in the conductivity tensor, the code can handle an arbitrary distribution function given by either an analytical function or numerical values on a momentum space grid and solve the full dispersion relation for an arbitrary propagation angle in either a non-relativistic or relativistic plasma except for a highly relativistic plasma (energy ⪢ 1 MeV). The results for cyclotron-maser instability and whistler-wave instability are presented to illustrate the validity of the method.
Relativistic ray-tracing of electron Bernstein waves in a spherical tokamak reactor
2007, Plasma Physics and Controlled Fusion
On electron Bernstein waves in spherical tori
2005, Journal of Plasma Physics
Ordinary waves in relativistic plasmas - Arbitrary wave propagation angle
1998, Plasma Physics and Controlled Fusion
Ordinary waves in relativistic plasmas
1998, Plasma Physics and Controlled Fusion
Characteristics of ordinary mode in fully relativistic electron plasma
2020, Plasma Physics and Controlled Fusion

View all citing articles on Scopus

View full text

Electromagnetic wave propagation in relativistic magnetized plasmas

Abstract

Principles of Plasma Physics

The Theory of Plasma Waves

Sov. Phys. JETP

Phys. Fluids