# The influence of atomic diffusion on stellar ages and chemical tagging

**Authors:** Aaron Dotter, Charlie Conroy, Phillip Cargile, Martin Asplund

arXiv: 1704.03465 · 2017-05-23

## TL;DR

Atomic diffusion significantly impacts stellar age estimates and chemical tagging accuracy, necessitating careful modeling of surface and initial abundances to improve Galactic archaeology studies.

## Contribution

This paper demonstrates the importance of accounting for atomic diffusion and extra mixing in stellar models to accurately determine ages and chemical signatures of stars.

## Key findings

- Atomic diffusion can cause overestimation of stellar ages by up to 20%.
- Surface abundances vary with evolutionary phase, affecting chemical tagging.
- Calibrating models may help estimate initial abundances and ages.

## Abstract

In the era of large stellar spectroscopic surveys, there is emphasis on deriving not only stellar abundances but also ages for millions of stars. In the context of Galactic archeology, stellar ages provide a direct probe of the formation history of the Galaxy. We use the stellar evolution code MESA to compute models with atomic diffusion--with and without radiative acceleration--and extra mixing in the surface layers. The extra mixing consists of both density-dependent turbulent mixing and envelope overshoot mixing. Based on these models we argue that it is important to distinguish between initial, bulk abundances (parameters) and current, surface abundances (variables) in the analysis of individual stellar ages. In stars that maintain radiative regions on evolutionary timescales, atomic diffusion modifies the surface abundances. We show that when initial, bulk metallicity is equated with current, surface metallicity in isochrone age analysis the resulting stellar ages can be systematically over-estimated by up to 20%. The change of surface abundances with evolutionary phase also complicates chemical tagging, the concept that dispersed star clusters can be identified through unique, high-dimensional chemical signatures. Stars from the same cluster, but in different evolutionary phases, will show different surface abundances. We speculate that calibration of stellar models may allow us to estimate not only stellar ages but also initial abundances for individual stars. In the meantime, analyzing the chemical properties of stars in similar evolutionary phases is essential to minimize the effects of atomic diffusion in the context of chemical tagging.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1704.03465/full.md

## References

74 references — full list in the complete paper: https://tomesphere.com/paper/1704.03465/full.md

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Source: https://tomesphere.com/paper/1704.03465