When LAMOST meets Gaia DR3 Exploring the metallicity of open clusters

TL;DR

This paper combines Gaia DR3 and LAMOST spectra to analyze open cluster metallicities, deriving their birth radii and migration patterns, and confirming metallicity gradients consistent with previous studies.

Contribution

It introduces a correction method for LAMOST data using GALAH spectra and estimates open cluster birth radii, advancing understanding of stellar migration in the Milky Way.

Findings

Metallicity gradient observed across the Galaxy.

LAMOST data correction reduces systematic offsets.

Many open clusters near the Sun originated from the outer disk.

Abstract

Context. Open clusters (OCs) are valuable probes of stellar population characteristics. Their age and metallicity provide insights into the chemical enrichment history of the Milky Way. By studying the metallicity of OCs, we can explore the spatial distribution of composition across the Galaxy and understand stellar birth radii through chemical tagging. However, inferring the original positions of OCs remains a challenge. Aims. This study investigates the distribution of metallicity in the solar neighborhood using data from Gaia DR3 and LAMOST spectra. By measuring accurate ages and metallicities, we aim to derive birth radii and understand stellar migration patterns. Methods. We selected 1131 OCs within 3 kpc of the Sun from Gaia DR3 and LAMOST DR8 low-resolution spectra (R=1800). To correct the LAMOST data, we incorporated high-resolution spectra from GALAH DR3 (R=28000) using an artificial neural network. The average metallicity of the OCs was derived from reliable [Fe/H] values of their members. We examined the metallicity distribution across the Galaxy and calculated birth radii based on age and metallicity. Results. The correction method reduces the systematic offset in LAMOST data. We found a metallicity gradient as a function of Galactocentric distance and guiding radii. Comparisons with chemo-dynamic simulations show that observed metallicity values are slightly lower than predicted when uncertainties are ignored, but the metallicity gradients align with previous studies. We also inferred that many OCs near the Sun likely originated from the outer Galactic disk.