Star formation efficiency in galaxy clusters

TL;DR

This study analyzes the distribution of baryonic matter in galaxy clusters, focusing on the ratio of stellar to gas mass and its dependence on cluster temperature, revealing that less massive clusters have higher star formation efficiency.

Contribution

It provides a combined analysis of X-ray and optical data to quantify baryon components and their relation to cluster temperature, highlighting the anti-correlation between stellar-to-gas mass ratio and temperature.

Findings

Stellar-to-gas mass ratio decreases with increasing cluster temperature.

Less massive clusters have higher star formation efficiency.

The ratio ranges from 24% to 6% across the sample.

Abstract

The luminous material in clusters of galaxies falls primarily into two forms: the visible galaxies and the X-ray emitting intra-cluster medium. The hot intra-cluster gas is the major observed baryonic component of clusters, about six times more massive than the stellar component. The mass contained within visible galaxies amounts to approximately 3% of the dynamical mass. Our aim was to analyze both baryonic components, combining X-ray and optical data of a sample of five galaxy clusters (Abell 496, 1689, 2050, 2631 and 2667), within the redshift range 0.03 < z < 0.3. We determined the contribution of stars in galaxies and the intra-cluster medium to the total baryon budget. We used public XMM-Newton data to determine the gas mass and to obtain the X-ray substructures. Using the optical counterparts from SDSS or CFHT we determined the stellar contribution. We examine the relative contribution of galaxies, intra-cluster light and intra-cluster medium to baryon budget in clusters through the stellar-to-gas mass ratio, estimated with use of recent data. We find that the stellar-to-gas mass ratio within r_500 (the radius which the mean cluster density exceeds the critical density by a factor of 500), is anti-correlated with the ICM temperature, ranging from 24% to 6% whereas the temperature ranges from 4.0 to 8.3 keV. This indicates that less massive cold clusters are more prolific star forming environments than massive hot clusters.