Wave dispersion in pulsar plasma: 1. Plasma rest frame

Abstract

Wave dispersion in a pulsar plasma (a 1D, strongly magnetized, pair plasma streaming highly relativistically with a large spread in Lorentz factors in its rest frame) is discussed, motivated by interest in beam-driven wave turbulence and the pulsar radio emission mechanism. In the rest frame of the pulsar plasma there are three wave modes in the low-frequency, non-gyrotropic approximation. For parallel propagation these are referred to as the X, A and L modes, with the X and A modes having dispersion relation z=zA≈1-1/2βA2, where z=ω/k c is the phase speed and βAc is the Alfven speed. The L mode dispersion relation is determined by a relativistic plasma dispersion function, z2W(z), which is negative for z < z0 and has a sharp maximum at z=zm, with 1-zm<1-z01. We give numerical estimates for the maximum of z2W(z) and for zm and z0 for a 1D Juttner distribution. The L and A modes reconnect, for zA>z0, to form the O and Alfven modes for oblique propagation (θ≠0). For zA<z0 the Alfven and O~mode curves reconnect forming a new mode that exists only for 2θ>z02-zA2. The L mode is the nearest counterpart to Langmuir waves in a nonrelativistic plasma, but we argue that there are no `Langmuir-like' waves in pulsar plasma, identifying three features of the L~mode (dispersion relation, ratio of electric to total energy and group speed) that are not Langmuir-like. A beam-driven instability requires a beam speed equal to the phase speed of the wave. This resonance condition can be satisfied for the O mode, but only for an implausibly energetic beam and only for a tiny range of angles for the O~mode around θ≈0. The resonance is also possible for the Alfven mode but only near a turnover frequency that has no counterpart for Alfven waves in a nonrelativistic plasma.