Constraining ultra-compact dwarf galaxy formation with galaxy clusters in the local universe

TL;DR

This study uses a semi-analytic model to compare predictions of ultra-compact dwarf galaxy formation via tidal stripping with observations in the Fornax and Virgo clusters, finding good agreement in numbers, properties, and black hole masses.

Contribution

It provides the first detailed comparison of tidal stripping models with observed UCDs and GCs in galaxy clusters, highlighting the role of stripped nuclei in high-mass UCD populations.

Findings

Predicted number of stripped nuclei matches observed excess of GCs+UCDs.

Stripped nuclei can explain UCDs with masses >10^{7.3} M_sun.

Predicted metallicities and black hole masses align with observations.

Abstract

We compare the predictions of a semi-analytic model for ultra-compact dwarf galaxy (UCD) formation by tidal stripping to the observed properties of globular clusters (GCs) and UCDs in the Fornax and Virgo clusters. For Fornax we find the predicted number of stripped nuclei agrees very well with the excess number of GCs$+$UCDs above the GC luminosity function. GCs$+$UCDs with masses $>10^{7.3}$ M$_\odot$ are consistent with being entirely formed by tidal stripping. Stripped nuclei can also account for Virgo UCDs with masses $>10^{7.3}$ M$_\odot$ where numbers are complete by mass. For both Fornax and Virgo, the predicted velocity dispersions and radial distributions of stripped nuclei are consistent with that of UCDs within $\sim$50-100 kpc but disagree at larger distances where dispersions are too high and radial distributions too extended. Stripped nuclei are predicted to have radially biased anisotropies at all radii, agreeing with Virgo UCDs at clustercentric distances larger than 50 kpc. However, ongoing disruption is not included in our model which would cause orbits to become tangentially biased at small radii. We find the predicted metallicities and central black hole masses of stripped nuclei agree well with the metallicities and implied black hole masses of UCDs for masses $>10^{6.5}$ M$_\odot$. The predicted black hole masses also agree well with that of M60-UCD1, the first UCD with a confirmed central black hole. These results suggest that observed GC$+$UCD populations are a combination of genuine GCs and stripped nuclei, with the contribution of stripped nuclei increasing toward the high-mass end.