The globular clusters and star formation history of the isolated, quiescent ultra-diffuse galaxy DGSAT I

TL;DR

This study of the ultra-diffuse galaxy DGSAT I reveals its globular cluster system, star formation history, and dark matter content, providing insights into its origin as a potential 'failed galaxy' in a low-density environment.

Contribution

First detailed analysis of globular clusters around an isolated UDG, linking their properties to the galaxy's star formation history and dark matter halo.

Findings

DGSAT I hosts 12±2 globular clusters.

Globular clusters are more compact than the galaxy's stars.

Evidence suggests an early, intense burst of cluster formation.

Abstract

We investigate the isolated, quiescent ultra-diffuse galaxy (UDG) DGSAT I and its globular cluster (GC) system using two orbits of Hubble Space Telescope Advanced Camera for Surveys imaging in the F606W and F814W filters. This is the first study of GCs around a UDG in a low-density environment. DGSAT I was previously found to host an irregular blue low surface brightness clump, that we confirm as very likely belonging to the galaxy rather than being a chance projection, and represents a recent episode of star formation (${\sim}500~\mathrm{Myr}$) that challenges some UDG formation scenarios. We select GC candidates based on colours and magnitudes, and construct a self consistent model of the GC radial surface density profile along with the background. We find a half-number radius of $R_\mathrm{GC} = 2.7\pm0.1~\mathrm{kpc}$ (more compact than the diffuse starlight) and a total of $12 \pm 2$ GCs. The total mass fraction in GCs is relatively high, supporting an overmassive dark matter halo as also implied by the high velocity dispersion previously measured. The GCs extend to higher luminosities than expected, and have colours that are unusually similar to their host galaxy colour, with a very narrow spread--all of which suggest an early, intense burst of cluster formation. The nature and origin of this galaxy remain puzzling, but the most likely scenario is a "failed galaxy" that formed relatively few stars for its halo mass, and could be related to cluster UDGs whose size and quiescence pre-date their infall.