Fossil Groups Origins: I. RX J105453.3+552102 a very massive and relaxed system at z~0.5

TL;DR

This study analyzes the massive, relaxed fossil galaxy system RX J105453.3+552102 at z~0.5, revealing its dynamical state, luminosity function, and galaxy properties, challenging some traditional fossil group definitions.

Contribution

First detailed dynamical and photometric analysis of RX J105453.3+552102, highlighting its massive, old, and undisturbed nature despite not fully meeting fossil group criteria.

Findings

System has a virial mass of ~10^{15} M_sun.

No evidence of substructure within 1.4 Mpc radius.

Luminosity function is bimodal with a slight deviation from classical fossil group criteria.

Abstract

The most accepted scenario for the origin of fossil groups (FGs) is that they are galaxy associations in which the merging rate was fast and efficient. These systems have assembled half of their mass at early epoch of the Universe, subsequently growing by minor mergers. They could contain a fossil record of the galaxy structure formation. We have started a project in order to characterize a large sample of FGs. In this paper we present the analysis of the fossil system RX J105453.3+552102. Optical deep images were used for studying the properties of the brightest group galaxy and for computing the photometric luminosity function of the group. We have also performed a detail dynamical analysis of the system based on redshift data for 116 galaxies. This galaxy system is located at z=0.47, and shows a quite large line-of-sight velocity dispersion \sigma_{v}~1000 km/s. Assuming the dynamical equilibrium, we estimated a virial mass of M ~ 10^{15} h_{70} M_{\odot}. No evidence of substructure was found within 1.4 Mpc radius. We found a statistically significant departure from Gaussianity of the group members velocities in the most external regions of the group. This could indicate the presence of galaxies in radial orbits in the external region of the group. We also found that the photometrical luminosity function is bimodal, showing a lack of M_{r} ~ -19.5 galaxies. The brightest group galaxy shows low Sersic parameter (n~2) and a small peculiar velocity. Indeed, our accurate photometry shows that the difference between the brightest and the second brightest galaxies is 1.9 mag in the r-band, while the classical definition of FGs is based on a magnitude gap of 2. We conclude that this fossil system does not follow the empirical definition of FGs. Nevertheless, it is a massive, old and undisturbed galaxy system with little infall of L^{*} galaxies since its initial collapse.