Dependence of kinetic plasma waves on ion-to-electron mass ratio and light-to-Alfv\'en speed ratio

Abstract

The magnetization | e|/ωe is an important parameter in plasma astrophysics, where e and ωe are the electron gyro-frequency and electron plasma frequency, respectively. It only depends on the mass ratio m i/m e and the light-to-Alfv\'en speed ratio c/vAi, where m i (m e) is the ion (electron) mass, c is the speed of light, and vAi is the ion Alfv\'en speed. Nonlinear numerical plasma models such as particle-in-cell simulations must often assume unrealistic values for m i/m e and for c/vAi. Because linear theory yields exact results for parametric scalings of wave properties at small amplitudes, we use linear theory to investigate the dispersion relations of Alfv\'en/ion-cyclotron and fast-magnetosonic/whistler waves as prime examples for collective plasma behaviour depending on m i/m e and c/vAi. We analyse their dependence on m i/m e and c/vAi in quasi-parallel and quasi-perpendicular directions of propagation with respect to the background magnetic field for a plasma with βj1, where βj is the ratio of the thermal to magnetic pressure for species j. Although their dispersion relations are largely independent of c/vAi for c/vAi 10, the mass ratio m i/m e has a strong effect at scales smaller than the ion inertial length. Moreover, we study the impact of relativistic electron effects on the dispersion relations. Based on our results, we recommend aiming for a more realistic value of m i/m e than for a more realistic value of c/vAi in non-relativistic plasma simulations if such a choice is necessary, although …