A group of merging galaxies falling onto Abell 2142

TL;DR

This study investigates a galaxy group falling into Abell 2142, analyzing its physical state, kinematics, and star formation activity to understand transformation processes in cluster environments.

Contribution

It provides detailed kinematic and stellar population analysis of an infalling galaxy group, revealing ongoing interactions and star formation enhancement prior to cluster integration.

Findings

Galaxies are mainly rotating disks with perturbed kinematics.

The long X-ray tail originates from intra-group medium, not ram-pressure stripping.

Star formation rate in the group is 45 solar masses per year.

Abstract

Galaxy clusters produce a very hostile environment to galaxies, whose gas gets stripped by ram-pressure, suffer galaxy interactions and witness quenching of their star formation. Clusters, like Abell 2142, grow not only through galaxy accretion but also through group infall. Our goal is to study the physical and dynamical state of the most conspicuous infalling group, on a filament projected at 1.3 Mpc from the Abell 2142 centre. The galaxy group is the leading edge of a spectacular trailing 700-kpc-long X-ray tail of hot gas stripped by ram-pressure. The infalling galaxies are not quenched yet, and are ideal objects to study the transformation processes due to the cluster environment. We use integral field spectroscopy from MaNGA to derive stellar and gas kinematics, and MegaCam for ugr photometry. Stellar populations (with age and metallicity) are obtained through full-spectrum fitting using Nburst. The gas kinematics and excitation are derived from the line emission of H$\alpha$, [NII], [OIII] and H$\beta$. The group contains four galaxies, of which two are merging and partly superposing on the line of sight. With a simple parametric model for each velocity field, we succeed in disentangling the contribution of each galaxy and derive their physical state and kinematics. The galaxies are perturbed, and intra-group gas is observed as tidal tails and loops. They are mainly disks in rotation, although some regions reveal elevated dispersion, typical of out-of-equilibrium gas. All galaxies show sustained star formation, with a global star formation rate of 45 M$_\odot$/yr. We conclude that the long X-ray tail must have come from the hot intra-group medium, present before the group infall, and does not correspond to the ram-pressure stripping of the galaxy gas. The galaxy interactions within the group are still enhancing the star formation, from the disks that are still rich in dense gas.