Diffusive acceleration in relativistic shocks: particle feedback

Abstract

The spectral index s of particles diffusively accelerated in a relativistic shock depends on the unknown angular diffusion function D, which itself depends on the particle distribution function f if acceleration is efficient. We develop a relaxation code to compute s and f for an arbitrary functional D that depends on f. A local D(f) dependence is motivated and shown, when rising (falling) upstream, to soften (harden) s with respect to the isotropic case, shift the angular distribution towards upstream (downstream) directions, and strengthen (weaken) the particle confinement to the shock; an opposite effect on s is found downstream. However, variations in s remain modest even when D is a strong function of f, so the standard, isotropic-diffusion results remain approximately applicable unless D is both highly anisotropic and not a local function of f. A mild, 0.1 softening of s, in both 2D and 3D, when D(f) rises sufficiently fast, may be indicated by ab-initio simulations.