1. The [Y/Mg] chemical clock in the Galactic Disk: The influence of metallicity and Galactic population in the solar neighbourhood
- Author
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Shejeelammal, J., Meléndez, Jorge, Rathsam, Anne, and Martos, Giulia
- Subjects
Astrophysics - Astrophysics of Galaxies ,Astrophysics - Solar and Stellar Astrophysics - 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., Comment: Accepted for publication in the section "8. Stellar atmospheres" of Astronomy & Astrophysics journal
- Published
- 2024
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