Tidal Interactions and Mergers in Intermediate Redshift EDisCS Clusters

TL;DR

This study investigates the frequency of tidal interactions and mergers in galaxies within intermediate redshift clusters, groups, and fields, analyzing their dependence on environment, redshift, and velocity dispersion using HST-ACS data.

Contribution

It introduces a combined visual and automated $G-M_{20}$ method to identify tidal interactions and mergers in galaxy clusters at intermediate redshifts.

Findings

Higher redshift may correlate with increased $f_{TIM}$, but evidence is marginal.

No significant trend between $f_{TIM}$ and velocity dispersion.

Enhanced $f_{TIM}$ observed in intermediate density environments like groups and cluster outskirts.

Abstract

We study the fraction of tidal interactions and mergers with well identified observability timescales ($f_{\rm TIM}$) in group, cluster, and accompanying field galaxies and its dependence on redshift ($z$), cluster velocity dispersion ($\sigma$) and environment analyzing HST-ACS images and catalogs from the ESO Distant Cluster Survey (EDisCS). Our sample consists of 11 clusters, 7 groups, and accompanying field galaxies at $0.4 \leq z \leq 0.8$. We derive $f_{\rm TIM}$ using both a visual classification of galaxy morphologies and an automated method, the $G-M_{20}$ method. We calibrate this method using the visual classifications that were performed on a subset of our sample. We find marginal evidence for a trend between $f_{\rm TIM}$ and $z$, in that higher $z$ values correspond to higher $f_{\rm TIM}$. However, we also cannot rule out the null hypothesis of no correlation at higher than 68% confidence. No trend is present between $f_{\rm TIM}$ and $\sigma$. We find that $f_{\rm TIM}$ shows suggestive peaks in groups, and tentatively in clusters at $R > 0.5\times R_{200}$, implying that $f_{\rm TIM}$ gets boosted in these intermediate density environments. However, our analysis of the local densities of our cluster sample does not reveal a trend between $f_{\rm TIM}$ and density, except for a potential enhancement at the very highest densities. We also perform an analysis of projected radius-velocity phase space for our cluster members. Our results reveal that tidal interactions and mergers (TIM), and undisturbed galaxies only have a 6% probability of having been drawn from the same parent population in their velocity distribution and 37% in radii, in agreement with the modest differences obtained in $f_{\rm TIM}$ at the clusters.