Physical properties of Brightest Cluster Galaxies up to redshift 1.80 based on HST data

TL;DR

This study analyzes the physical properties of Brightest Cluster Galaxies up to redshift 1.8 using HST data, finding evidence that they mainly formed before redshift 2 and evolved through accretion along cosmic filaments.

Contribution

It introduces a new method to identify BCGs in clusters and provides a homogeneous analysis of their properties across a wide redshift range.

Findings

BCGs follow the Kormendy relation with a constant slope over redshift.

Absolute magnitudes and effective radii of BCGs tend to brighten and grow with decreasing redshift.

No significant correlation of Sersic index or mean surface brightness with redshift.

Abstract

Brightest cluster galaxies (BCGs) have grown by accreting numerous smaller galaxies and can be used as tracers of cluster formation and evolution in the cosmic web. However, there is still a controversy on the main epoch of formation of BCGs, since some authors believe they have already formed before redshift z=2, while others still find them to evolve at more recent epochs. We aim to analyse the physical properties of a large sample of BCGs covering a wide redshift range up to z=1.8 and analysed in a homogeneous way, to see if their characteristics vary with redshift. As a first step, we also present a new tool to define for each cluster which galaxy is the BCG. For a sample of 137 clusters with HST images in the optical and/or infrared, we analyse the BCG properties by applying GALFIT with one or two Sersic components. For each BCG, we compute the Sersic index, effective radius, major axis position angle, surface brightness. We then search for correlations of these quantities with redshift. We find that BCGs follow the Kormendy relation (between the effective radius and the mean surface brightness), with a slope that remains constant with redshift, but with a variation with redshift of the ordinate at the origin. Although the trends are faint, we find that both the absolute magnitudes and effective radii tend to become respectively brighter and bigger with decreasing redshift. On the other hand, we find no significant correlation of the mean surface brightnesses or Sersic indices with redshift. The major axes of the cluster elongations and of the BCGs agree within 30 degrees for 73% of our clusters at redshift z <= 0.9. Our results agree with the BCGs being mainly formed before redshift z=2. The alignment of the major axes of BCGs with their clusters agree with the general idea that BCGs form at the same time as clusters by accreting matter along the filaments of the cosmic web.