Stationary Bernstein-Greene-Kruskal structures in a current carrying relativistic cold plasma

Abstract

Nonlinear stationary structures formed in a cold plasma with immobile ions in the presence of a relativistic electron current beam have been investigated analytically in the collisionless limit. These are cold plasma version of the relativistic Berstein-Greene-Kruskal (BGK) waves. The structure profile is governed by the ratio of maximum electrostatic field energy density to the relativistic kinetic energy density of the electron beam, i.e., R = Em/ (8 π n0 (γ0-1)m0 c2)1/2, where Em is the maximum electric field associated with the nonlinear structure and γ0 is the Lorentz factor associated with the beam velocity. It is found that, in the linear limit, i.e., R 1/γ0, the fluid variables, viz, density, electric field, and velocity vary harmonically in space. In the range 0 < R ≤ 1/γ0, the fluid variables exhibit an-harmonic behavior. For values of R > 1/γ0, the electric field shows finite discontinuities at specific spatial locations indicating the formation of negatively charged planes at these locations.