The AMBRE Project: Origin and evolution of sulfur in the Milky Way

TL;DR

This study provides the largest and most precise catalog of sulfur abundances in stars, revealing its nucleosynthesis origin, distribution, and relation to galactic evolution, using extensive spectral data and automated analysis.

Contribution

It offers the first large-scale, precise sulfur abundance catalog for 1855 stars, clarifying sulfur's behavior across different metallicities and galactic components.

Findings

[S/M] ratio shows a plateau at low metallicity and decreases at higher metallicity.

Sulfur-rich stars have distinct kinematic and orbital properties.

Galactic sulfur gradients and age-related abundance trends are characterized.

Abstract

Sulfur is a volatile chemical element that plays an important role in tracing the chemical evolution of galaxies. However, its nucleosynthesis origin and abundance variations are still unclear. The goal of the present article is to accurately and precisely study the S-content of large number of stars located in the solar neighbourhood. We use the parametrisation of thousands of HR stellar spectra provided by the AMBRE Project, and combine it with the automated abundance determination GAUGUIN to derive LTE sulfur abundances for 1855 slow-rotating FGK-type stars. This is the largest and most precise catalogue of S-abundances published to date. It covers a metallicity domain as high as ~2.5dex starting at [M/H]~-2.0dex. We find that the [S/M] abundances ratio is compatible with a plateau-like distribution in the metal-poor regime, and then starts to decrease continuously at [M/H]~-1.0dex. This decrease continues towards negative values for supersolar metallicity stars as recently reported for Mg and as predicted by Galactic chemical evolution models. Moreover, sulfur-rich stars having [M/H] in the range [-1.0,-0.5] have very different kinematical and orbital properties with respect to more metal-rich and sulfur-poor ones. Two disc components, associated with the thin and thick discs, are thus seen independently in kinematics and sulfur abundances. The sulfur radial gradients in the Galactic discs have also been estimated. Finally, the enrichment in sulfur with respect to iron is nicely correlated with stellar ages: older metal-poor stars have higher [S/M] ratios than younger metal-rich ones. This work has confirmed that sulfur is an alfa-element that could be considered to explore the Galactic populations properties.