Photometric and Structural Parameters of Newly Discovered Nuclear Star Clusters in Local Volume Galaxies

TL;DR

This study uses high-resolution Hubble data to analyze 19 nuclear star clusters in nearby dwarf galaxies, revealing correlations with host galaxy mass, environmental effects, and links to globular clusters.

Contribution

It provides the first detailed parameterization of newly discovered NSCs in local dwarf galaxies, highlighting environmental influences on their scaling relations and formation mechanisms.

Findings

Most NSCs have stellar masses below 10^6 solar masses.

Surface brightness at the effective radius correlates with host galaxy mass.

Environmental dependence affects the scaling relation slope between NSCs and galaxy mass.

Abstract

We use high-resolution Hubble Space Telescope imaging data of dwarf galaxies in the Local Volume ($\lesssim 11$ Mpc) to parameterise 19 newly discovered nuclear star clusters (NSCs). Most of the clusters have stellar masses of $M_{\star}^{nsc} \lesssim 10^6$ M$_{\odot}$ and compare to Galactic globular clusters in terms of ellipticity, effective radius, stellar mass, and surface density. The clusters are modelled with a S\'ersic profile and their surface brightness evaluated at the effective radius reveals a tight positive correlation to the host galaxy stellar mass. Our data also indicate an increase in slope of the density profiles with increasing mass, perhaps indicating an increasing role for in-situ star formation in more massive hosts. We evaluate the scaling relation between the clusters and their host galaxy stellar mass to find an environmental dependence: for NSCs in field galaxies, the slope of the relation is $\alpha = 0.82^{+0.08}_{-0.08}$ whereas $\alpha = 0.55^{+0.06}_{-0.05}$ for dwarfs in the core of the Virgo cluster. Restricting the fit for the cluster to $M_{\star}^{gal} \geq 10^{6.5}$ M$_{\odot}$ yields $\alpha = 0.70^{+0.08}_{-0.07}$, in agreement with the field environment within the $1\sigma$ interval. The environmental dependence is due to the lowest-mass nucleated galaxies and we speculate that this is either due to an increased number of progenitor globular clusters merging to become an NSC, or due to the formation of more massive globular clusters in dense environments, depending on the initial globular cluster mass function. Our results clearly corroborate recent results in that there exists a tight connection between NSCs and globular clusters in dwarf galaxies.