The structure of TeV-bright shell-type supernova remnants

TL;DR

This study uses 2D MHD simulations to model the emission and morphology of TeV-bright shell-type supernova remnants, revealing complex structures and the influence of turbulent ambient media on their observed properties.

Contribution

The paper demonstrates that 2D MHD simulations in turbulent media can reproduce the observed features of TeV-bright SNRs, highlighting the role of turbulence in their morphology and emission.

Findings

Simulations confirm shock evolution and magnetic field amplification mechanisms.

Reproduces complex gamma-ray morphologies suggesting intrinsic source variations.

Matches observed radial brightness profiles with low ambient densities.

Abstract

Aims. Two-dimensional MHD simulations are used to model the emission properties of TeV-bright shell-type supernova remnants (SNRs) and to explore their nature. Methods. In the leptonic scenario for the TeV emission, the $\gamma$-ray emission is produced via Inverse Compton scattering of background soft photons by high-energy electrons accelerated by the shocks of the SNRs. The TeV emissivity is proportional to the magnetic field energy density and MHD simulations can be used to model the TeV structure of such remnants directly. 2D MHD simulations for SNRs are then performed under the assumption that the ambient interstellar medium is turbulent with the magnetic field and density fluctuations following a Kolmogorov-like power-law spectrum. Results. (1) As expected, these simulations confirm early 1D and 2D modelings of these sources, namely the hydrodynamical evolution of the shock waves and amplification of magnetic field by Rayleigh-Taylor convective flows and by shocks propagating in a turbulent medium; (2) We reproduce rather complex morphological structure for $\gamma$-rays, suggesting intrinsic variations of the source morphology not related to the structure of the progenitor and environment; (3)The observed radial profile of several remnants are well reproduced with an ambient medium density of $0.1-1$ cm$^{-3}$. An even lower ambient density leads to a sharper drop of the TeV brightness with radius than what is observed near the outer edge of these remnants. Conclusions. In a turbulent background medium, we can reproduce the observed characteristics of several shell-type TeV SNRs with reasonable parameters except for a higher ambient density than that inferred from X-ray observations.