English

Diffusive shock acceleration in $N$ dimensions

High Energy Astrophysical Phenomena 2020-07-07 v1

Abstract

Collisionless shocks are often studied in two spatial dimensions (2D), to gain insights into the 3D case. We analyze diffusive shock acceleration for an arbitrary number NNN\in\mathbb{N} of dimensions. For a non-relativistic shock of compression ratio R\mathcal{R}, the spectral index of the accelerated particles is sE=1+N/(R1)s_E=1+N/(\mathcal{R}-1); this curiously yields, for any NN, the familiar sE=2s_E=2 (i.e., equal energy per logarithmic particle energy bin) for a strong shock in a mono-atomic gas. A precise relation between sEs_E and the anisotropy along an arbitrary relativistic shock is derived, and is used to obtain an analytic expression for sEs_E in the case of isotropic angular diffusion, affirming an analogous result in 3D. In particular, this approach yields sE=(1+13)/22.30s_E = (1+\sqrt{13})/2 \simeq 2.30 in the ultra-relativistic shock limit for N=2N=2, and sE(N)=2s_E(N\to\infty)=2 for any strong shock. The angular eigenfunctions of the isotropic-diffusion transport equation reduce in 2D to elliptic cosine functions, providing a rigorous solution to the problem; the first function upstream already yields a remarkably accurate approximation. We show how these and additional results can be used to promote the study of shocks in 3D.

Keywords

Cite

@article{arxiv.2002.11123,
  title  = {Diffusive shock acceleration in $N$ dimensions},
  author = {Assaf Lavi and Ofir Arad and Yotam Nagar and Uri Keshet},
  journal= {arXiv preprint arXiv:2002.11123},
  year   = {2020}
}

Comments

14 pages, 7 figures, comments welcome

R2 v1 2026-06-23T13:53:41.747Z