The results of a previous investigation of growing electromagnetic waves in a gyrotropic electron plasma are now extended to relativistic electron energies. If γ is the ratio of the longitudinal to the transverse electron thermal energy, then a nonrelativistic analysis predicts instabilities for both γ 1. However, for γ > 1 the phase velocity of the growing waves exceeds the velocity of light in vacuo and it is inconceivable that there are electrons that interact strongly with such a wave to give a finite growth rate. The relativistic analysis clears up this difficulty by predicting no instability for γ > 1; the error lies in the use of a Galilean rather than the correct Lorentz transformation to go from the wave frame to the frame in which the electrons are at rest. A criterion for the existence of such instabilities is given. The case of a beam of electrons with γ « 1 drifting at a relativistic velocity v0 through a cold isotropic plasma is also analyzed to be unstable. The growth rates, fre...
[1]
P. Noerdlinger.
GROWING TRANSVERSE WAVES IN A PLASMA IN A MAGNETIC FIELD
,
1963
.
[2]
R. Sudan.
PLASMA ELECTROMAGNETIC INSTABILITIES
,
1963
.
[3]
H. Furth.
Prevalent Instability of Nonthermal Plasmas
,
1963
.
[4]
Burton D. Fried,et al.
The Plasma Dispersion Function
,
1961
.
[5]
O. Penrose.
Electrostatic Instabilities of a Uniform Non‐Maxwellian Plasma
,
1960
.
[6]
Norman Rostoker,et al.
Test Particles in a Completely Ionized Plasma
,
1960
.
[7]
E. S. Weibel,et al.
Spontaneously Growing Transverse Waves in a Plasma Due to an Anisotropic Velocity Distribution
,
1959
.
[8]
Burton D. Fried,et al.
Mechanism for Instability of Transverse Plasma Waves
,
1959
.
[9]
R. Post.
Controlled Fusion Research-An Application of the Physics of High Temperature Plasmas
,
1956,
Proceedings of the IRE.