Age-resolved chemistry of red giants in the solar neighbourhood

TL;DR

This study analyzes age-abundance relationships in 721 solar neighborhood red giants using APOGEE data, revealing key trends that inform models of Galactic chemical evolution and stellar migration.

Contribution

It provides detailed age-abundance relations for multiple elements in red giants, confirming known trends and offering new insights into Galactic chemical evolution and stellar migration.

Findings

Steep and narrow [{}/M]-age relation with 0.20 dex dispersion

Complex [M/H]-age relation with broad dispersion

Oldest stars at lowest and highest metallicities, youngest at solar metallicity

Abstract

In the age of high-resolution spectroscopic stellar surveys of the Milky Way, the number of stars with detailed abundances of multiple elements is rapidly increasing. These elemental abundances are directly influenced by the evolutionary history of the Galaxy, but this can be difficult to interpret without an absolute timeline of the abundance enrichment. We present age-abundance trends for [M/H], [{\alpha}/M], and 17 individual elements using a sample of 721 solar neighbourhood Hipparcos red giant stars observed by APOGEE. These age trends are determined through a Bayesian hierarchical modelling method presented by Feuillet et al. (2016). We confirm that the [{\alpha}/M]- age relation in the solar neighbourhood is steep and relatively narrow (0.20 dex age dispersion), as are the [O/M]- and [Mg/M]-age relations. The age trend of [C/N] is steep and smooth, consistent with stellar evolution. The [M/H]-age relation has a mean age dispersion of 0.28 dex and a complex overall structure. The oldest stars in our sample are those with the lowest and highest metallicities, while the youngest stars are those with solar metallicity. These results provide strong constraints on theoretical models of Galactic chemical evolution (GCE). We compare them to the predictions of one-zone GCE mod- els and multi-zone mixtures, both analytic and numerical. These comparisons support the hypothesis that the solar neighbourhood is composed of stars born at a range of Galactocentric radii, and that the most metal-rich stars likely migrated from a region with earlier and more rapid star formation such as the inner Galaxy.