H-alpha emitters in z~2 proto-clusters: evidence for faster evolution in dense environments

TL;DR

This study reveals that galaxy proto-clusters at z~2 have significantly higher star formation densities and more massive, earlier-formed galaxies compared to the field, indicating accelerated galaxy evolution in dense environments.

Contribution

It provides the first detailed comparison of H-alpha emitters in proto-clusters and the field at z~2, showing environment-driven differences in galaxy growth and star formation history.

Findings

Proto-clusters contain 12-14 times more H-alpha emitters than the field.

Star formation density is 13 times higher in proto-clusters.

Proto-cluster galaxies are more massive and formed stars earlier.

Abstract

This is a study of H-alpha emitters in two dense galaxy proto-clusters surrounding radio galaxies at z~2. We show that the proto-cluster surrounding MRC 1138-262 contains 14+/-2 times more H-alpha candidates than the average field (9 sigma significance), and the z=2.35 radio galaxy 4C+10.48 is surrounded by 12+/-2 times more emitters than the field (5 sigma), so it is also likely to reside in a dense proto-cluster environment. We compared these H-alpha emitters, situated in dense environments, to a control field sample selected from 3 separate fields forming a total area of 172 arcmin^2. We constructed and compared H-alpha and rest-frame R continuum luminosity functions of the emitters in both environments. The star formation density is on average 13 times greater in the proto-clusters than the field at z~2, so the total star formation rate within the central 1.5Mpc of the proto-clusters exceeds 3000Msun/yr. However, we found no significant difference in the shape of the H-alpha luminosity functions, implying that environment does not substantially affect the strength of the H-alpha line from strongly star forming galaxies. The proto-cluster emitters are typically 0.8mag brighter in rest-frame R continuum than field emitters, implying they are twice as massive as their field counterparts at the same redshift. We also show the proto-cluster galaxies have lower specific star formation rates than field galaxies, meaning the emitters in the dense environments formed more of their stars earlier than the field galaxies. We conclude that galaxy growth in the early Universe was accelerated in dense environments, and that cluster galaxies differed from field galaxies even before the cluster had fully formed.