Mass Distribution in Galaxy Clusters: the Role of AGN Feedback

TL;DR

This study uses high-resolution cosmological simulations to examine how AGN feedback influences the distribution of mass in galaxy clusters, addressing overcooling issues and matching observations.

Contribution

It demonstrates that incorporating AGN feedback resolves overcooling problems and aligns simulated mass distributions with observed galaxy cluster properties.

Findings

AGN feedback reduces stellar mass in the BCG below observed levels.

Gas and total mass distributions match observations when AGN feedback is included.

Baryon distribution shows a slight deficit at the virial radius due to AGN-driven shocks.

Abstract

We use 1 kpc resolution cosmological AMR simulations of a Virgo-like galaxy cluster to investigate the effect of feedback from supermassive black holes (SMBH) on the mass distribution of dark matter, gas and stars. We compared three different models: (i) a standard galaxy formation model featuring gas cooling, star formation and supernovae feedback, (ii) a "quenching" model for which star formation is artificially suppressed in massive halos and finally (iii) the recently proposed AGN feedback model of Booth & Schaye (2009). Without AGN feedback (even in the quenching case), our simulated cluster suffers from a strong overcooling problem, with a stellar mass fraction significantly above observed values in M87. The baryon distribution is highly concentrated, resulting in a strong adiabatic contraction (AC) of dark matter. With AGN feedback, on the contrary, the stellar mass in the bright central galaxy (BCG) lies below observational estimates and the overcooling problem disappears. The stellar mass of the BCG is seen to increase with increasing mass resolution, suggesting that our stellar masses converges to the correct value from below. The gas and total mass distributions are in striking agreement with observations. We also find a slight deficit (~10%) of baryons at the virial radius, due to the effect of AGN-driven shock waves pushing gas to Mpc scales and beyond. This baryon deficit results in a slight adiabatic expansion of the dark matter distribution, that can be explained quantitatively by AC theory.