The IMACS Cluster Building Survey: II. Spectral Evolution of Galaxies in the Epoch of Cluster Assembly

TL;DR

This study analyzes spectral data of galaxies in clusters and the field to understand galaxy evolution, revealing that starbursts and poststarbursts are common but not primary quenching mechanisms, with passive galaxies mainly formed through major mergers and less violent processes.

Contribution

It provides new insights into galaxy spectral evolution across environments, highlighting the roles of mergers, starvation, and tidal stripping in galaxy quenching and transformation.

Findings

Starbursts and poststarbursts are common across environments.

Preprocessing in groups influences galaxy quenching before cluster infall.

Major mergers and gentle processes are primary in forming passive galaxies.

Abstract

The IMACS Cluster Building Survey (ICBS) provides spectra of ~2200 galaxies 0.31<z<0.54 in 5 rich clusters (R <= 5 Mpc) and the field. Infalling, dynamically cold groups with tens of members account for approximately half of the supercluster population, contributing to a growth in cluster mass of ~100% by today. The ICBS spectra distinguish non-starforming (PAS) and poststarburst (PSB) from starforming galaxies -- continuously starforming (CSF) or starbursts, (SBH or SBO), identified by anomalously strong H-delta absorption or [O II] emission. For the infalling cluster groups and similar field groups, we find a correlation between PAS+PSB fraction and group mass, indicating substantial "preprocessing" through quenching mechanisms that can turn starforming galaxies into passive galaxies without the unique environment of rich clusters. SBH + SBO starburst galaxies are common, and they maintain an approximately constant ratio (SBH+SBO)/CSF ~ 25% in all environments -- from field, to groups, to rich clusters. Similarly, while PSB galaxies strongly favor denser environments, PSB/PAS ~ 10-20% for all environments. This result, and their timescale tau < 500 Myr, indicates that starbursts are not signatures of a quenching mechanism that produces the majority of passive galaxies. We suggest instead that starbursts and poststarbursts signal minor mergers and accretions, in starforming and passive galaxies, respectively, and that the principal mechanisms for producing passive systems are (1) early major mergers, for elliptical galaxies, and (2) later, less violent processes -- such as starvation and tidal stripping, for S0 galaxies.