Studying galaxy evolution through cosmic time via the {\mu}Jy radio population: early results from eMERGE

TL;DR

The eMERGE survey uses high-resolution radio observations to study galaxy evolution and star formation across cosmic time, providing detailed insights into galaxy structures and activity up to redshift 5.

Contribution

This paper presents early results from the first data release of the eMERGE survey, showcasing its unprecedented combination of depth, resolution, and coverage at 1.4GHz for studying galaxy evolution.

Findings

High-resolution imaging of galaxies reveals detailed morphologies.

Detection of cold dust properties in radio-selected galaxies.

Localization of star-forming regions and AGN activity.

Abstract

The $e$MERLIN Galaxy Evolution Survey ($e$MERGE) is an ambitious, multi-tiered extragalactic radio continuum survey being carried out with $e$MERLIN and the VLA at 1.4GHz and 6GHz. Exploiting the unique combination of high sensitivity and high angular resolution provided by radio interferometry, these observations will provide a powerful, obscuration-independent tool for tracing intense star-formation and AGN activity in galaxies out to $z\sim5$. In our first data release (DR1) we present $e$MERGE Tier 1, a 15-arcmin pointing centred on the GOODS-N field, imaged at 1.4GHz with the VLA and $e$MERLIN at $\sim 0.28''$ resolution down to an rms sensitivity of $\sim 1.2\,\mu$Jy beam$^{-1}$. This unique radio survey -- unrivaled at 1.4GHz in its combination of depth, areal coverage and angular resolution in the pre-SKA era -- allows us to localise and separate extended star-forming regions, nuclear starbursts and compact AGN core/jet systems in galaxies over the past two-thirds of cosmic history, a crucial step in tracing the apparently simultaneous growths of the stellar populations and central black holes in massive galaxies. In these proceedings we highlight some early science results from $e$MERGE DR1, including some examples of the sub-arcsecond morphologies and cold dust properties of 1.4GHz-selected galaxies. $e$MERGE Tier 1 will eventually reach sub-$\mu$Jy beam$^{-1}$ sensitivity at $0.28''$ resolution over a 30-arcmin field, providing crucial benchmarks for deep extragalactic surveys which will be undertaken with SKA in the next decade.