The evolution of the Milky Way: New insights from open clusters

TL;DR

This study analyzes the chemical and kinematic properties of open clusters in the Milky Way to understand their formation, evolution, and the galaxy's metallicity gradient, revealing differences based on age, location, and orbital history.

Contribution

It provides new high-resolution spectroscopic data for 12 open clusters and clarifies the relationship between cluster properties, metallicity gradients, and Galactic structure.

Findings

Steeper metallicity gradient within 12 kpc of the Galactic center.

Outer disc clusters likely formed inward and migrated outward.

Consistent metallicity gradients between clusters and field stars at similar heights.

Abstract

We have collected high-dispersion echelle spectra of red giant members in the twelve open clusters (OCs) and derived stellar parameters and chemical abundances for 26 species by either line equivalent widths or synthetic spectrum analyses. We confirm the lack of an age-metallicity relation for OCs but argue that such a lack of trend for OCs arise from the limited coverage in metallicity compared to that of field stars which span a wide range in metallicity and age. We confirm that the radial metallicity gradient of OCs is steeper (flatter) for Rgc < 12 kpc (> 12 kpc). We demonstrate that the sample of clusters constituting a steep radial metallicity gradient of slope $-$0.052$\pm$0.011 dex kpc$^{-1}$ at Rgc < 12 kpc are younger than 1.5 Gyr and located close to the Galactic midplane (|z| < 0.5 kpc) with kinematics typical of the thin disc. Whereas the clusters describing a shallow slope of $-$0.015$\pm$0.007 dex kpc$^{-1}$ at Rgc > 12 kpc are relatively old, thick disc members with a striking spread in age and height above the midplane (0.5 < |z| < 2.5 kpc). Our investigation reveals that the OCs and field stars yield consistent radial metallicity gradients if the comparison is limited to samples drawn from the similar vertical heights. We argue via the computation of Galactic orbits that all the outer disc clusters were actually born inward of 12 kpc but the orbital eccentricity has taken them to present locations very far from their birthplaces.