The LEGARE Project. I. Chemical evolution model of the Nuclear Stellar Disc in a Bayesian framework

TL;DR

This paper develops a Bayesian chemical evolution model for the Milky Way's Nuclear Stellar Disc, revealing that metal-poor inflows are necessary to explain observed metallicity distributions, with implications for star formation and gas accretion history.

Contribution

It introduces the first Bayesian chemical evolution model for the NSD, incorporating bar-driven gas inflows and testing different formation scenarios against observed data.

Findings

Dilution from metal-poor inflows is needed to match MDFs without contamination assumptions.

Best-fit model suggests inflow metallicity five times lower than inner disc.

Model reproduces observed abundance ratios and star formation history.

Abstract

The Nuclear Stellar Disc (NSD) of the Milky Way is a dense, rotating stellar system in the central 200 pc. The NSD is thought to be primarily fuelled by bar-driven gas inflows from the inner Galactic disc. As part of the LEGARE project, we construct the first chemical evolution models for the NSD using a Bayesian approach tailored to reproduce the observed metallicity distribution functions (MDFs) and compared with the available abundance ratios for Mg, Si, Ca relative to Fe. We adopt a state-of-the-art chemical evolution model in which the gas responsible for the formation of the NSD is assumed to be driven by the Galactic bar-induced inflows. The chemical composition of the accreted material is assumed to reflect that of the Galactic disc at a radius of 4 kpc. A Bayesian MCMC framework is used to fit the MDFs of different samples of NSD stars. If we take the NSD data at face value, without considering a possible contamination from bulge stars, we find that a formation scenario based on the inner disc flowing gas is inconsistent with the low metallicity tail of the observed MDF. This is because the inner disc metallicity, at the epoch of bar formation, was already near solar. On the other hand, models invoking dilution from additional metal-poor inflows successfully reproduce the observations. The best-fit model requires inflow metallicity 5 times lower than the inner disc and a moderate star formation efficiency. The same model successfully reproduces the observed [$\alpha$/Fe] vs. [Fe/H] ratios and predicts a star formation history consistent with the most recent estimates. However, if we assume that the MDF is contaminated by metal poor bulge stars and restricted to [Fe/H] > -0.3 dex, gas dilution is no longer required. In this case, the best-fit model has a very low star formation efficiency and a mild galactic wind.