Thermal radio absorption as a tracer of the interaction of SNRs with their environments

TL;DR

This study analyzes the radio spectra of 14 supernova remnants using low-frequency data to understand their interactions with surrounding environments, revealing thermal absorption effects indicative of such interactions.

Contribution

It provides new high-resolution spectral maps and identifies thermal absorption features in multiple SNRs, advancing understanding of SNR-environment interactions at low radio frequencies.

Findings

Detection of thermal absorption in multiple SNRs.

Identification of spectral breaks in pulsar wind nebulae.

Correlation of low-frequency turnovers with ionized gas interactions.

Abstract

We present new images and continuum spectral analysis for 14 resolved Galactic SNRs selected from the 74 MHz Very Large Array Low-Frequency Sky Survey Redux (VLSSr). We combine new integrated measurements from the VLSSr with flux densities extracted from the GLEAM and measurements from the literature to generate improved continuum spectra. We combine the VLSSr images with publicly available images at 1.4 GHz, to analyse the resolved morphology and spectral index distribution across each SNR. Three of the SNRs, Kepler, G28.6-0.1, and Tycho, have integrated spectra which can be adequately fit with simple power laws. The resolved spectral index map for Tycho confirms internal absorption which was previously detected by the LOFAR, but it is insufficient to affect the fit to the integrated spectrum. For the pulsar wind nebulae G21.5-0.9 and 3C58 we identify high-frequency spectral breaks at 38 and 12 GHz, respectively. A low frequency spectral turnover adequately fits the data of the remaining nine SNRs. For Kes 67, Kes 69, Kes75, and 3C397, we attribute the absorption to ionised gas along the line of sight, possibly from extended HII region envelopes. For W41 the absorption can be attributed to HII regions located in its immediate proximity. Thermal absorption from interactions at the ionised interface between SNR forward shocks and the surrounding medium were previously identified as responsible for the low frequency turnover in SNR 3C391; our integrated spectrum is consistent with the previous results. We present evidence for the same phenomenon in three additional SNRs, Kes73, W49B, and 3C396, and derive constraints on the physical properties of the interaction. This result indicates that interactions between SNRs and their environs should be readily detectable through thermal absorption by future low frequency observations of SNRs with improved sensitivity and resolution.