The chemical signature of the Galactic spiral arms revealed by Gaia DR3

TL;DR

Using Gaia DR3 data, this study maps chemical inhomogeneities in the Milky Way's disc, revealing that spiral arms significantly influence the metallicity patterns of young stars, while older stars show smoother gradients.

Contribution

This paper provides the first detailed mapping of chemical inhomogeneities associated with spiral arms across different stellar populations in the Milky Way using Gaia DR3 data.

Findings

Younger stars show metal-rich features aligned with spiral arms.

Older stars exhibit a smooth radial metallicity gradient.

Spiral arms imprint a strong chemical signature on young stellar populations.

Abstract

Taking advantage of the recent Gaia Data Release 3 (DR3), we map chemical inhomogeneities in the Milky Way's disc out to a distance of $\sim$ 4 kpc from the Sun, using different samples of bright giant stars. The samples are selected using effective temperatures and surface gravities from the GSP-Spec module, and are expected to trace stellar populations of different typical age. The cool (old) giants exhibit a relatively smooth radial metallicity gradient with an azimuthal dependence. Binning in Galactic azimuth $\phi$, the slope gradually varies from $d$[M/H]$/dR \sim -0.054$ dex kpc$^{-1}$ at $\phi \sim -20^{\circ}$ to $\sim -0.035$ dex kpc$^{-1}$ at $\phi \sim 20^{\circ}$. On the other hand, the relatively hotter (and younger) stars present remarkable inhomogeneities, apparent as three (possibly four) metal-rich elongated features in correspondence of the spiral arms' locations in the Galactic disc. When projected onto Galactic radius, those features manifest themselves as statistically significant bumps on top of the observed radial metallicity gradients with amplitudes up to $ \sim 0.05-0.1$ dex, making the assumption of a linear radial decrease not applicable to this sample. The strong correlation between the spiral structure of the Galaxy and the observed chemical pattern in the young sample indicates that the spiral arms might be at the origin for the detected chemical inhomogeneities. In this scenario, the spiral arms would leave in the younger stars a strong signature, which progressively disappears when cooler (and older) giants are considered.