The Next Generation Fornax Survey (NGFS): IV. Mass and Age Bimodality of Nuclear Clusters in the Fornax Core Region

TL;DR

This study analyzes 61 nucleated dwarf galaxies in the Fornax cluster, revealing a bimodal distribution of nuclear cluster masses and distinct stellar populations, challenging existing formation models.

Contribution

It provides new insights into the mass, age, and metallicity bimodality of nuclear clusters, and tests theoretical models against observed trends in galaxy nuclei.

Findings

Nuclei show a bimodal mass distribution with peaks at log(M*/Msun) ≈ 5.4 and 6.3.

More massive nuclei are older than 2 Gyr and metal-poor, while less massive are younger and more metal-rich.

The nucleus-to-galaxy mass ratio decreases with galaxy mass, reaching 10% in low-mass galaxies.

Abstract

We present the analysis of 61 nucleated dwarf galaxies in the central regions ($<R_{\rm vir}/4$) of the Fornax galaxy cluster. The galaxies and their nuclei are studied as part of the Next Generation Fornax Survey (NGFS) using optical imaging obtained with the Dark Energy Camera (DECam) mounted at Blanco/CTIO and near-infrared data obtained with VIRCam at VISTA/ESO. We decompose the nucleated dwarfs in nucleus and spheroid, after subtracting the surface brightness profile of the spheroid component and studying the nucleus using PSF photometry.In general, nuclei are consistent with colors of confirmed metal-poor globular clusters, but with significantly smaller dispersion than other confirmed compact stellar systems in Fornax. We find a bimodal nucleus mass distribution with peaks located at $\log({\cal M_*}/M_\odot)\!\simeq\!5.4$ and $\sim\,6.3$. These two nucleus sub-populations have different stellar population properties, the more massive nuclei are older than $\sim\!2$ Gyr and have metal-poor stellar populations ($Z\leq0.02\,Z_\odot$), while the less massive nuclei are younger than $\sim\!2$ Gyr with metallicities in the range $0.02\!<\!Z/Z_\odot\!\leq\!1$. We find that the nucleus mass (${\cal M}_{\rm nuc}$) vs. galaxy mass (${\cal M}_{\rm gal}$) relation becomes shallower for less massive galaxies starting around $10^8\,M_\odot$ and the mass ratio $\eta_n\!=\!{\cal M}_{\rm nuc}/{\cal M}_{\rm gal}$ shows a clear anti-correlation with ${\cal M}_{\rm gal}$ for the lowest masses, reaching $10\%$. We test current theoretical models of nuclear cluster formation and find that they cannot fully reproduce the observed trends. A likely mixture of in-situ star formation and star-cluster mergers seem to be acting during nucleus growth over cosmic time.