Relativistic Spherical Shocks in Expanding Media

Abstract

We investigate the propagation of spherically symmetric shocks in relativistic homologously expanding media with density distributions following a power-law profile in their Lorentz factor. That is, ej t-3γe(R,t)-α, where ej is the medium proper density, γe is its Lorentz factor, α>0 is constant and t, R are the time and radius from the center. We find that the shocks behavior can be characterized by their proper velocity, U'=s'βs', where s' is the shock Lorentz factor as measured in the immediate upstream frame and βs' is the corresponding 3-velocity. While generally, we do not expect the shock evolution to be self-similar, for every α>0 we find a critical value U'c for which a self-similar solution with constant U' exists. We then use numerical simulations to investigate the behavior of general shocks. We find that shocks with U'>U'c have a monotonously growing U', while those with U'<U'c have a decreasing U' and will eventually die out. Finally, we present an analytic approximation, based on our numerical results, for the evolution of general shocks in the regime where U' is ultra-relativistic.