Analytic study of 1D diffusive relativistic shock acceleration

Diffusive shock acceleration (DSA) by relativistic shocks is thought to generate the $dN/dE\propto E^{-p}$ spectra of charged particles in various astronomical relativistic flows. We show that for test particles in one dimension (1D), $p^{-1}=1-\ln\left[\gamma_d(1+\beta_d)\right]/\ln\left[\gamma_u(1+\beta_u)\right]$, where $\beta_u$ ($\beta_d)$ is the upstream (downstream) normalized velocity, and $\gamma$ is the respective Lorentz factor. This analytically captures the main properties of relativistic DSA in higher dimensions, with no assumptions on the diffusion mechanism. Unlike 2D and 3D, here the spectrum is sensitive to the equation of state even in the ultra-relativistic limit, and (for a J{\"u}ttner-Synge equation of state) noticeably hardens with increasing $1<\gamma_u<57$, before logarithmically converging back to $p(\gamma_u\to\infty)=2$. The 1D spectrum is sensitive to drifts, but only in the downstream, and not in the ultra-relativistic limit.