Saved in:
Bibliographic Details
Main Authors: Monty, Stephanie, Strom, Allison L., Stanton, Thomas M., Chruślińska, Martyna, Cullen, Fergus, Kobayashi, Chiaki, Starkenburg, Tjitske, Bhattacharya, Souradeep, Sanders, Jason L., Gieles, Mark
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.14094
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916866727870464
author Monty, Stephanie
Strom, Allison L.
Stanton, Thomas M.
Chruślińska, Martyna
Cullen, Fergus
Kobayashi, Chiaki
Starkenburg, Tjitske
Bhattacharya, Souradeep
Sanders, Jason L.
Gieles, Mark
author_facet Monty, Stephanie
Strom, Allison L.
Stanton, Thomas M.
Chruślińska, Martyna
Cullen, Fergus
Kobayashi, Chiaki
Starkenburg, Tjitske
Bhattacharya, Souradeep
Sanders, Jason L.
Gieles, Mark
contents Our understanding of the chemical evolution of galaxies has advanced through measurements from both distant galaxies across redshift, and our own Milky Way (MW). To form a comprehensive picture, it is essential to unify these constraints, placing them on a common scale and parlance and to understand their systematic differences. In this study, we homogenize oxygen and iron measurements from star-forming galaxies at Cosmic Noon ($z{\sim}2-3$) with resolved stellar abundances from the Local Group. The MW is divided into four components, assuming the outer halo is dominated by debris from the Gaia-Sausage-Enceladus (GSE) progenitor. After converting all abundances to a common Solar scale, we identify clear $α$- and iron-enhancement trends with mass in the $z{\sim}2-3$ galaxies and find good agreement between these galaxies and the MW high-$α$ disc in [O/Fe] vs. [Fe/H]. We also find excellent agreement between the [O/Fe] trends seen in the MW high- and low-$α$ discs with O-abundances seen in old and young planetary nebulae in M~31 respectively, supporting the existence of $α$-bimodality in the inner regions of M~31. Finally, we use globular cluster ages to project the MW and GSE back in time to $z{\sim}3$ and find that their estimated mass, oxygen and iron abundances are strikingly consistent with the mass-metallicity relation of star-forming galaxies at $z{\sim}3$. In the future, increased transparency around the choice of Solar scale and abundance methodology will make combining chemical abundances easier -- contributing to a complete picture of the chemical evolution of all galaxies.
format Preprint
id arxiv_https___arxiv_org_abs_2507_14094
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle ChemZz I: Comparing Oxygen and Iron Abundance Patterns in the Milky Way, the Local Group and Cosmic Noon
Monty, Stephanie
Strom, Allison L.
Stanton, Thomas M.
Chruślińska, Martyna
Cullen, Fergus
Kobayashi, Chiaki
Starkenburg, Tjitske
Bhattacharya, Souradeep
Sanders, Jason L.
Gieles, Mark
Astrophysics of Galaxies
Our understanding of the chemical evolution of galaxies has advanced through measurements from both distant galaxies across redshift, and our own Milky Way (MW). To form a comprehensive picture, it is essential to unify these constraints, placing them on a common scale and parlance and to understand their systematic differences. In this study, we homogenize oxygen and iron measurements from star-forming galaxies at Cosmic Noon ($z{\sim}2-3$) with resolved stellar abundances from the Local Group. The MW is divided into four components, assuming the outer halo is dominated by debris from the Gaia-Sausage-Enceladus (GSE) progenitor. After converting all abundances to a common Solar scale, we identify clear $α$- and iron-enhancement trends with mass in the $z{\sim}2-3$ galaxies and find good agreement between these galaxies and the MW high-$α$ disc in [O/Fe] vs. [Fe/H]. We also find excellent agreement between the [O/Fe] trends seen in the MW high- and low-$α$ discs with O-abundances seen in old and young planetary nebulae in M~31 respectively, supporting the existence of $α$-bimodality in the inner regions of M~31. Finally, we use globular cluster ages to project the MW and GSE back in time to $z{\sim}3$ and find that their estimated mass, oxygen and iron abundances are strikingly consistent with the mass-metallicity relation of star-forming galaxies at $z{\sim}3$. In the future, increased transparency around the choice of Solar scale and abundance methodology will make combining chemical abundances easier -- contributing to a complete picture of the chemical evolution of all galaxies.
title ChemZz I: Comparing Oxygen and Iron Abundance Patterns in the Milky Way, the Local Group and Cosmic Noon
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2507.14094