The [Y/Mg] chemical clock in the Galactic Disk: The influence of metallicity and Galactic population in the solar neighbourhood

TL;DR

This study investigates the [Y/Mg] chemical clock's reliability across different metallicities and Galactic populations, demonstrating its strong age correlation and validating its use for diverse stellar populations in the Galactic disk.

Contribution

It provides the first detailed calibration of the [Y/Mg] chemical clock for both thin and thick disk stars across a wide metallicity range, improving age estimation accuracy.

Findings

Strong anti-correlation between [Y/Mg] and stellar age.

Validates [Y/Mg] as an age indicator for thin and thick disk stars.

Achieves higher age estimation precision than previous studies.

Abstract

Stellar ages are an important parameter to study the chemical evolution of the Galaxy. In recent years, several studies have established the existence of a relationship between chemical clocks and stellar ages. The [Y/Mg] clock is a promising technique, but there are still several open questions, such as its validity for metal-poor stars and differences between the thin and thick disk populations. Our aim is to study the behaviour of the [Y/Mg] chemical clock with stellar ages and the effect of metallicity and population on this chemical clock for a sample of solar-type disk stars. We have derived the precise stellar atmospheric parameters as well as the elemental abundances of Mg and Y through line-by-line differential spectroscopic analysis for a sample of 48 metal-poor solar-type stars based on high-quality, high-resolution ESO/HARPS spectra. From the high-precision Gaia astrometric data, stellar masses and ages were estimated through isochrone-fitting. A joint analysis of our sample, together with a sample of 185 solar-twins and analogues from our previous works, is performed to calibrate the [Y/Mg] chemical clock in the Galactic disk for $-$0.71 $\leq$ [Fe/H] $<$ +0.34. Open clusters and stars with asteroseismic ages have been used to validate our relations. Two different populations could be clearly seen in the [Mg/Fe] - [Fe/H] plane - the thick and thin disks. We found a metallicity-dependent, strong anti-correlation between the [Y/Mg] ratio and stellar ages of our sample. For the first time in the literature, we report similar correlations for the thin and thick disk stars. The [Y/Mg] relation(s) found here for solar-type stars is compatible with the literature using solar-twins. Our relation provides higher accuracy and precision of 0.45 and 0.99 Gyr, respectively, comparable with the best accuracy achieved for the solar-twins till date.