Carbon, oxygen, and iron abundances in disk and halo stars. Implications of 3D non-LTE spectral line formation

TL;DR

This study provides detailed 3D non-LTE spectral line formation calculations for key elements in stars, significantly refining abundance measurements and revealing insights into stellar populations and planetary signatures.

Contribution

It introduces new 3D non-LTE correction grids for stellar abundances, improving accuracy over traditional 1D LTE methods and enabling better analysis of stellar populations.

Findings

3D non-LTE corrections can be as large as -0.6 dex for oxygen lines.

Applying corrections reduces scatter in abundance plots.

Planet-hosting stars tend to have higher C/O ratios after correction.

Abstract

The abundances of carbon, oxygen, and iron in late-type stars are important parameters in exoplanetary and stellar physics, as well as key tracers of stellar populations and Galactic chemical evolution. We carried out three-dimensional (3D) non-LTE radiative transfer calculations for CI and OI, and 3D LTE radiative transfer calculations for FeII, across the STAGGER-grid of 3D hydrodynamic model atmospheres. The absolute 3D non-LTE versus 1D LTE abundance corrections can be as severe as $-0.3$ dex for CI lines in low-metallicity F dwarfs, and $-0.6$ dex for OI lines in high-metallicity F dwarfs. The 3D LTE versus 1D LTE abundance corrections for FeII lines are less severe, typically less than $+0.15$ dex. We used the corrections in a re-analysis of carbon, oxygen, and iron in $187$ F and G dwarfs in the Galactic disk and halo. Applying the differential 3D non-LTE corrections to 1D LTE abundances visibly reduces the scatter in the abundance plots. The thick disk and high-$\alpha$ halo population rise in carbon and oxygen with decreasing metallicity, and reach a maximum of [C/Fe]$\approx0.2$ and a plateau of [O/Fe]$\approx0.6$ at [Fe/H]$\approx-1.0$. The low-$\alpha$ halo population is qualitatively similar, albeit offset towards lower metallicities and with larger scatter. Nevertheless, these populations overlap in the [C/O] versus [O/H] plane, decreasing to a plateau of [C/O]$\approx-0.6$ below [O/H]$\approx-1.0$. In the thin-disk, stars having confirmed planet detections tend to have higher values of C/O at given [O/H]; this potential signature of planet formation is only apparent after applying the abundance corrections to the 1D LTE results. Our grids of line-by-line abundance corrections are publicly available and can be readily used to improve the accuracy of spectroscopic analyses of late-type stars.