The stellar mass composition of galaxy clusters and dependencies on dark matter halo properties

TL;DR

This study uses hydrodynamical simulations to analyze the stellar mass distribution in galaxy clusters, revealing how the ICL and BCG masses relate to cluster properties and the processes shaping them.

Contribution

It provides new insights into the dependencies of stellar mass components on dark matter halo properties and the effects of mergers and tidal stripping in cluster evolution.

Findings

ICL fraction is nearly independent of cluster mass at certain apertures.

More concentrated and earlier assembled clusters have higher stellar mass loss from satellites.

Ex-situ stars dominate both BCG and ICL, with different contributions from mergers and tidal stripping.

Abstract

We analyze 700 clusters from the TNG300 hydrodynamical simulation ($M_{200}\geq5\times10^{13} \,M_{\odot}$ at (z=0)) to examine the radial stellar mass distribution of their central objects, consisting of the brightest cluster galaxy (BCG) and the intracluster light (ICL). The BCG+ICL mass fraction weakly anticorrelates with $M_{200}$, but strongly correlates with the concentration, $c_{200}$, the assembly redshift, $z_{50}$, and the mass gap between the most massive and the fourth more massive member, $\Delta M_{\rm \ast, 4th}$. We explore different aperture radii to nominally separate the ICL from the BCG and calculate ICL fractions. For $r_{\rm{ap}}=2r_{\rm half}$, where $r_{\rm half}$ is the radius containing half the BCG+ICL mass, the ICL fraction is nearly independent of $M_{200}$, $c_{200}$, and $z_{50}$ with values $M_{\ast,\rm ICL}/(M_{\ast,\rm ICL}+M_{\ast,\rm BCG})= 0.33\pm0.03$. Including the stellar mass of the satellites, the fraction $M_{\ast,\rm ICL}/(M_{\ast,\rm ICL}+M_{\ast,\rm BCG}+M_{\rm \ast,sat})$ weakly anticorrelates with $M_{200}$ and strongly correlates with $c_{200}$, $z_{50}$, and $\Delta M_{\rm \ast, 4th}$, suggesting that in more concentrated/earlier assembled/more relaxed clusters more stellar mass is lost from the satellites (by tidal stripping, and mergers) in favour of the ICL and BCG. Indeed, we find that ex-situ stars dominate both in the BCG and ICL masses, with mergers contributing more to the BCG, while tidal stripping contributes more to the ICL. We find that the difference between the projected and 3D ICL fractions are only a few per cent and suggest using $2r_{\rm half}$ to separate the ICL from the BCG in observed clusters.