Probing the farthest star clusters to the Small Magellanic Cloud

TL;DR

This study investigates three distant star clusters in the Small Magellanic Cloud using deep imaging and astrometric data, revealing their properties, kinematics, and evidence of tidal interactions with the Large Magellanic Cloud.

Contribution

It provides detailed analysis of the most external SMC star clusters, including their parameters and dynamics, highlighting tidal effects from the LMC.

Findings

Lindsay 116 shows strong tidal perturbations.

Clusters have similar ages (~2.2 Gyr) and moderate metallicity.

Lindsay 116 appears kinematically older and affected by LMC tides.

Abstract

The Small Magellanic Cloud (SMC) has been tidally shaped by the interaction with the Large Magellanic Cloud (LMC). The scope of such an interaction has recently been studied from different astrophysical properties of its star cluster population, which point to star clusters placed remarkably outside the known extension of the galaxy. In this work we report results for three of the recently identified most external SMC star clusters, OGLE-CL-SMC0133, OGLE-CL-SMC0237, and Lindsay~116, using deep GEMINI GMOS imaging. Once we confidently cleaned their color-magnitude diagrams from field star contamination, we estimated their fundamental parameters applying likelihood techniques. We also derived their structural parameters from normalized star number density radial profiles. Based on {\it Gaia} astrometric data, complemented with kinematics information available in the literature, we computed the 3D components of their space velocities. With similar ages (~ 2.2 Gyr) and moderately metal-poor overall abundances ([Fe/H] = -1.0 - -0.7 dex), OGLE-CL-SMC0237 is placed at 2.6 kpc from the SMC center and shares its disk rotation; OGLE-CL-SMC0133 is located at 7.6 kpc from the galaxy center and exhibits a kinematics marginally similar to the SMC rotation disk, while Lindsay~116 placed at 15.7 kpc from the center of the SMC is facing strong perturbations of its orbital motion with respect to an ordered rotational trajectory. Furthermore, its internal dynamical evolution would seem to be accelerated -- it seems kinematically older -- in comparison with star clusters in the outskirts of relatively isolated galaxies. These outcomes lead to conclude that Lindsay~116 is subject to LMC tides.