The relationship between age, metallicity, and abundances for disk stars in a simulated Milky Way galaxy

TL;DR

This study uses cosmological simulations to analyze how age, metallicity, and element abundances relate in Milky Way-like disk stars, revealing small intrinsic scatter and metallicity dependence consistent with observations.

Contribution

It demonstrates that FIRE-2 simulations reproduce observed age-[X/Fe] relations and their small scatter, providing insights into the physical conditions shaping chemical evolution.

Findings

Small intrinsic scatter in age-[X/Fe] relations (0.01-0.04 dex).

Metallicity-dependent scatter, with lower values at higher [Fe/H].

Inner galaxy stars show higher scatter and older ages.

Abstract

Observations of the Milky Way's low-$\alpha$ disk show that at fixed metallicity, [Fe/H], several element abundance, [X/Fe], correlate with age, with unique slopes and small scatters around the age-[X/Fe] relations. In this study, we turn to simulations to explore the age-[X/Fe] relations for the elements C, N, O, Mg, Si, S, and Ca that are traced in a FIRE-2 cosmological zoom-in simulation of a Milky Way-like galaxy, m12i, and understand what physical conditions give rise to the observed age-[X/Fe] trends. We first explore the distributions of mono-age populations in their birth and current locations, [Fe/H], and [X/Fe], and find evidence for inside-out radial growth for stars with ages < 7 Gyr. We then examine the age-[X/Fe] relations across m12i's disk and find that the direction of the trends agree with observations, apart from C, O, and Ca, with remarkably small intrinsic scatters, $\sigma_{int}$ (0.01-0.04 dex). This $\sigma_{int}$ measured in the simulations is also metallicity-dependent, with $\sigma_{int}$ $\approx$ 0.025 dex at [Fe/H]=-0.25 dex versus $\sigma_{int}$ $\approx$ 0.015 dex at [Fe/H]=0 dex, and a similar metallicity dependence is seen in the GALAH survey for the elements in common. Additionally, we find that $\sigma_{int}$ is higher in the inner galaxy, where stars are older and formed in less chemically-homogeneous environments. The age-[X/Fe] relations and the small scatter around them indicate that simulations capture similar chemical enrichment variance as observed in the Milky Way, arising from stars sharing similar element abundances at a given birth place and time.