The chemical evolution of the solar neighbourhood for planet-hosting stars

Pignatari, Marco; Trueman, Thomas C L; Womack, Kate A; Gibson, Brad K; Côté, Benoit; Turrini, Diego; Sneden, Christopher; Mojzsis, Stephen J; Stancliffe, Richard J; Fong, Paul; Lawson, Thomas V; Keegans, James D; Pilkington, Kate; Passy, Jean-Claude; Beers, Timothy C; Lugaro, Maria

doi:10.1093/mnras/stad2167

The chemical evolution of the solar neighbourhood for planet-hosting stars

Pignatari, Marco; Trueman, Thomas C L; Womack, Kate A; Gibson, Brad K; Côté, Benoit; Turrini, Diego; Sneden, Christopher; Mojzsis, Stephen J; Stancliffe, Richard J; Fong, Paul; Lawson, Thomas V; Keegans, James D; Pilkington, Kate; Passy, Jean-Claude; Beers, Timothy C; Lugaro, Maria

Authors

Marco Pignatari

Thomas C L Trueman

Kate A Womack

Brad K Gibson

Benoit Côté

Diego Turrini

Christopher Sneden

Stephen J Mojzsis

Richard J Stancliffe

Paul Fong

Thomas V Lawson

James D Keegans

Kate Pilkington

Jean-Claude Passy

Timothy C Beers

Maria Lugaro

Abstract

Theoretical physical-chemical models for the formation of planetary systems depend on data quality for the Sun’s composition, that of stars in the solar neighbourhood, and of the estimated ”pristine” compositions for stellar systems. The effective scatter and the observational uncertainties of elements within a few hundred parsecs from the Sun, even for the most abundant metals like carbon, oxygen and silicon, are still controversial. Here we analyse the stellar production and the chemical evolution of key elements that underpin the formation of rocky (C, O, Mg, Si) and gas/ice giant planets (C, N, O, S). We calculate 198 galactic chemical evolution (GCE) models of the solar neighbourhood to analyse the impact of different sets of stellar yields, of the upper mass limit for massive stars contributing to GCE (Mup) and of supernovae from massive-star progenitors which do not eject the bulk of the iron-peak elements (faint supernovae). Even considering the GCE variation produced via different sets of stellar yields, the observed dispersion of elements reported for stars in the Milky Way disk is not reproduced. Among others, the observed range of super-solar [Mg/Si] ratios, sub-solar [S/N], and the dispersion of up to 0.5 dex for [S/Si] challenge our models. The impact of varying Mup depends on the adopted supernova yields. Thus, observations do not provide a constraint on the Mup parametrization. When including the impact of faint supernova models in GCE calculations, elemental ratios vary by up to 0.1-0.2 dex in the Milky Way disk; this modification better reproduces observations.

Citation

Pignatari, M., Trueman, T. C. L., Womack, K. A., Gibson, B. K., Côté, B., Turrini, D., …Lugaro, M. (in press). The chemical evolution of the solar neighbourhood for planet-hosting stars. Monthly Notices of the Royal Astronomical Society, https://doi.org/10.1093/mnras/stad2167

Journal Article Type	Article
Acceptance Date	Jul 21, 2023
Online Publication Date	Jul 21, 2023
Deposit Date	Aug 7, 2023
Publicly Available Date	Aug 7, 2023
Journal	Monthly Notices of the Royal Astronomical Society
Print ISSN	0035-8711
Publisher	Oxford University Press
Peer Reviewed	Peer Reviewed
DOI	https://doi.org/10.1093/mnras/stad2167
Keywords	Space and Planetary Science, Astronomy and Astrophysics