Radio-continuum spectra of ram pressure stripped galaxies in the Coma Cluster

TL;DR

This study uses high-resolution radio observations of the Coma Cluster to analyze the spectral properties of ram pressure stripped galaxies, revealing spectral gradients and estimating plasma velocities to understand the impact of ram pressure on galaxy evolution.

Contribution

It provides the first detailed spectral index maps of ram pressure stripped galaxies in Coma, constraining the impact on star formation and estimating plasma velocities from synchrotron aging.

Findings

Stripped tails have steep spectral indices (-2 to -1).

Galaxies' discs show spectral indices consistent with shock acceleration.

Spectral index gradients align with radio tails, indicating ram pressure effects.

Abstract

$Aims:$ We used the nearby Coma Cluster as a laboratory in order to probe the impact of ram pressure on star formation as well as to constrain the characteristic timescales and velocities for the stripping of the non-thermal ISM. $Methods:$ We used high-resolution ($6.5'' \approx 3\,\mathrm{kpc}$), multi-frequency ($144\,\mathrm{MHz} - 1.5\,\mathrm{GHz}$) radio continuum imaging of the Coma Cluster to resolve the low-frequency radio spectrum across the discs and tails of 25 ram pressure stripped galaxies. With resolved spectral index maps across these galaxy discs, we constrained the impact of ram pressure perturbations on galaxy star formation. We measured multi-frequency flux-density profiles along each of the ram pressure stripped tails in our sample. We then fit the resulting radio continuum spectra with a simple synchrotron aging model. $Results:$ We showed that ram pressure stripped tails in Coma have steep ($-2 \lesssim \alpha \lesssim -1$) spectral indices. The discs of galaxies undergoing ram pressure stripping have integrated spectral indices within the expected range for shock acceleration from supernovae ($-0.8 \lesssim \alpha \lesssim -0.5$), though there is a tail towards flatter values. In a resolved sense, there are gradients in spectral index across the discs of ram pressure stripped galaxies in Coma. These gradients are aligned with the direction of the observed radio tails, with the flattest spectral indices being found on the `leading half'. From best-fit break frequencies we estimated the projected plasma velocities along the tail to be on the order of hundreds of kilometers per second, with the precise magnitude depending on the assumed magnetic field strength.