Star Clusters in Tidal Debris

TL;DR

This study uses HST imaging to analyze star clusters in tidal tails of merging galaxies, revealing their age, mass distribution, formation efficiency, and physical properties, and confirming theoretical models of cluster formation.

Contribution

It provides new detailed measurements of star clusters in tidal debris, including their ages, masses, sizes, and formation efficiencies, across multiple systems with improved imaging data.

Findings

Mass distribution follows a power law with slope -2.02.

Cluster formation efficiency increases with star formation rate surface density.

Most clusters are gravitationally bound, with low-mass formation in NGC 1487.

Abstract

We present results of a Hubble Space Telescope (HST) UBVI-band study of star clusters in tidal tails, using new WFC3 and ACS imaging to complement existing WFPC2 data. We survey 12 tidal tails across seven merging systems, deriving ages and masses for 425 star cluster candidates (SCCs). The stacked mass distribution across all systems follows a power law of the form $dN/dM \propto M^{\beta}$, with $\beta = -2.02 \pm 0.15$, consistent with what is seen in other star forming environments. GALEX and Swift UV imaging provide star formation rates (SFRs) for our tidal tails, which when compared with ages and masses of our SCCs, allows for a determination of the cluster formation efficiency (CFE). We find the CFE increases with increasing SFR surface density, matching the theoretical model. We confirm this fit down at SFR densities lower than previously measured (log $\Sigma_\text{SFR} \: (\text{M}_\odot \: \text{yr}^{-1} \: \text{kpc}^{-2}) \approx -4.2$), as related to the CFE. We determine the half-light radii for a refined sample of 57 SCCs with our HST WFC3 and ACS imaging, and calculate their dynamical age, finding the majority of them to be gravitationally bound. We also provide evidence of only low-mass ($< 10^4 \: \text{M}_\odot$) cluster formation in our nearest galaxy, NGC 1487, consistent with the theory that this system is a dwarf merger.