Spectroscopic metallicities for Fornax UCDs, GCs and dE,Ns

TL;DR

This study provides spectroscopic metallicity measurements for Fornax UCDs, GCs, and dE,N nuclei, revealing a metallicity break at M_V~-11 mag and supporting a formation scenario involving merged young massive clusters rather than stripped nuclei.

Contribution

It offers the first spectroscopic metallicity estimates for a sample of Fornax UCDs and compares their properties with GCs and dE,N nuclei, proposing a dominant formation channel involving merged young massive clusters.

Findings

Metallicity break at M_V~-11 mag in compact objects.

Fornax UCDs are more metal-rich than dE,N nuclei.

UCD properties suggest formation from merged young massive clusters.

Abstract

Various formation channels for the puzzling ultra-compact dwarf galaxies (UCDs) have been proposed in the last few years. To better judge on some of the competing scenarios, we present spectroscopic [Fe/H] estimates for a sample of 26 compact objects in the central region of the Fornax cluster, covering the magnitude range of UCDs and bright globular clusters. We find a break in the metallicity distribution of compact objects at M_V ~ -11 mag (~3*10^6 M_sun): for M_V<-11 mag the mean metallicity is [Fe/H]=-0.62 +/- 0.05 dex, 0.56 +/- 0.15 dex higher than for M_V>-11 mag. This metallicity break is accompanied by a change in the size-luminosity relation for compact objects, as deduced from HST-imaging: for M_V<-11 mag, r_h scales with luminosity, while for M_V>-11 mag, r_h is almost luminosity-independent. We therefore assume a limiting absolute magnitude of M_V=-11 mag between UCDs and globular clusters. The mean metallicity of five Fornax dE,N nuclei included in our study is about 0.8 dex lower than that of the UCDs, at 4.5 sigma significance. Because of this large metallicity discrepancy we disfavor the hypothesis that most of the Fornax UCDs are the remnant nuclei of tidally stripped dE,Ns. Our metallicity estimates for UCDs are closer to but slightly below those derived for young massive clusters (YMCs) of comparable masses. We therefore favor a scenario where most UCDs in Fornax are successors of merged YMCs produced in the course of violent galaxy-galaxy mergers. It is noted that in contrast to that, the properties of Virgo UCDs are more consistent with the stripping scenario, suggesting that different UCD formation channels may dominate in either cluster.