Chemical analysis of the Milky Way's Nuclear Star Cluster: Evidence for a metallicity gradient

TL;DR

This study refines stellar parameters of the Milky Way's Nuclear Star Cluster using improved spectral analysis, revealing a metallicity gradient that supports an inside-out formation scenario.

Contribution

It provides a detailed metallicity map of the MWNSC with improved stellar parameters, highlighting a significant metallicity gradient and the presence of both metal-rich and metal-poor populations.

Findings

Identification of a metallicity gradient of ~-0.1 dex/pc

Detection of a ~20% metal-poor population at [M/H] ≈ -0.7

Most stars are part of a metal-rich population at [M/H] ≈ 0.26

Abstract

The Milky Way nuclear star cluster (MWNSC) is located together with its surrounding nuclear stellar disc (MWNSD) in the Galactic centre and they dominate the gravitational potential within the inner 300\,pc. However, the formation and evolution of both systems and their possible connections are still under debate. We reanalyse the low-resolution KMOS spectra in the MWNSC with the aim to improve the stellar parameters ($\rm T_{eff}$, $\rm \log\,g$, and $\rm [M/H])$ for the MWNSC. We use an improved line-list, especially dedicated for cool M giants allowing to improve the stellar parameters and to obtain in addition global $\rm \alpha$-elements. A comparison with high-resolution IR spectra (IGRINS) gives very satisfactory results pinning down the uncertainties to $\rm T_{eff} \simeq 150\,K$, $\rm log\,g \simeq 0.4\,dex$, and $\rm [M/H] \simeq 0.2\,dex$. Our $\rm \alpha$-elements agree within 0.1\,dex compared to the IGRINS spectra. We obtain a high-quality sample of 1140 M giant stars where we see an important contribution of a metal-poor population ($\rm \sim 20\,\%$) centered at $\rm [M/H] \simeq -0.7\,dex$ while the most dominant part comes from the metal-rich population with $\rm [M/H] \simeq 0.26\,dex$. We construct a metallicity map and find a metallicity gradient of $\rm \sim -0.1 \pm 0.02 \,dex/pc$ favouring the inside-out formation scenario for the MWNSC.