Constraining the formation of NGC1052-DF2 from its unusual globular cluster population

TL;DR

This paper investigates the unusual globular cluster system of the ultra-diffuse galaxy NGC1052-DF2, proposing it formed under extreme conditions during a major merger, which influenced its current low surface brightness and dark matter content.

Contribution

It introduces a theoretical model linking the galaxy's globular cluster properties to its formation environment, suggesting a merger origin for DF2's peculiar GC population and structural evolution.

Findings

GCs formed in high-density, high-rotation environments similar to starbursts

High cluster formation efficiency (>78%) during formation epoch

Formation likely occurred during a major merger at redshift ~1.3

Abstract

The ultra-diffuse galaxy (UDG) NGC1052-DF2 has a low dark matter content and hosts a very unusual globular cluster (GC) population, with a median luminosity $\sim4$ times higher than in most galaxies and containing about 5~per~cent of the galaxy's stars. We apply a theoretical model that predicts the initial cluster mass function as a function of the galactic environment to investigate the origin of DF2's peculiar GC system. Using the GC mass function, the model constrains the star-forming conditions in the galaxy during the formation of its GCs, $\sim9~\rm{Gyr}$ ago. We predict that the GCs formed in an environment with very high gas surface density, $\Sigma_{\rm ISM} \gtrsim 10^3 M_{\odot} \rm{pc}^{-2}$, and strong centrifugal support, $\Omega \gtrsim 0.7~\rm{Myr}^{-1}$, similar to nearby circum-nuclear starbursts and the central region of the Milky Way. These extreme conditions required to form the observed GC population imply a very high cluster formation efficiency of $\gtrsim 78$ per cent, and contrast strongly with the current diffuse nature of the galaxy. Since a nuclear starburst would lead to the rapid in-spiral of the GCs and is ruled out by the absence of a nuclear star cluster, we propose that the GCs plausibly formed during a major merger at $z\sim1.3$. The merger remnant must have undergone significant expansion of its stellar (and perhaps also its dark matter) component to reach its low present surface brightness, leading to the interesting possibility that it was the formation of DF2's extreme GC population that caused it to become a UDG. If true, this strong structural evolution would have important implications for understanding the origins of UDGs.