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Main Authors: Ness, Melissa K., Aquilina, Sarah, Mead, Jennifer, Griffith, Emily, Manea, Catherine, Bird, Jonathan, Casey, Andrew R., Lucy, Lu, Johnston, Kathryn V., Blanton, Michael R., Johnson, James W., Jablonska, Maja, Carigi, Leticia, Fernández-Trincado, José G., Valdivia, Ricardo López, Song, Ying-Yi, Kollmeier, Juna
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.21735
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author Ness, Melissa K.
Aquilina, Sarah
Mead, Jennifer
Griffith, Emily
Manea, Catherine
Bird, Jonathan
Casey, Andrew R.
Lucy
Lu
Johnston, Kathryn V.
Blanton, Michael R.
Johnson, James W.
Jablonska, Maja
Carigi, Leticia
Fernández-Trincado, José G.
Valdivia, Ricardo López
Song, Ying-Yi
Kollmeier, Juna
author_facet Ness, Melissa K.
Aquilina, Sarah
Mead, Jennifer
Griffith, Emily
Manea, Catherine
Bird, Jonathan
Casey, Andrew R.
Lucy
Lu
Johnston, Kathryn V.
Blanton, Michael R.
Johnson, James W.
Jablonska, Maja
Carigi, Leticia
Fernández-Trincado, José G.
Valdivia, Ricardo López
Song, Ying-Yi
Kollmeier, Juna
contents The element abundances of Milky Way disc stars encode entangled imprints of multiple enrichment processes, making it difficult to uncover the underlying chemical evolution. Here we re-project 16 stellar abundances for 199,290 red giant stars ([Fe/H]$ > -1$) into a set of (4) shared enrichment patterns, providing a generative framework for learning the organising structure of the Milky Way disc. The relative contributions of these patterns vary systematically across the disc, revealing a low-dimensional enrichment basis that responds coherently to global drivers of disc evolution. By grouping stars according to their pattern contributions, we identify coherent enrichment pathways that exhibit strong chemo-spatial correlations and are stratified in both age and height above the plane, linking radial growth to vertical disc structure. Stars occupying similar positions along these enrichment pathways also show coherent vertical deviations across radius, indicating that the low-dimensional chemical structure captures the disc's response to dynamical perturbations. We identify a transition in enrichment behaviour at approximately 6 Gyr, marking the onset of a more chemically mixed regime with increasing contributions from delayed sources. Within this connected system, the observed $α$-bimodality arises within a shared, low-dimensional abundance structure, with stars populating continuous sequences of changing enrichment fractions that are tightly coupled to spatial, temporal, and orbital coordinates across the Milky Way disc.
format Preprint
id arxiv_https___arxiv_org_abs_2605_21735
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Milky Way Mapper decoded abundances -- II: From patterns to paths
Ness, Melissa K.
Aquilina, Sarah
Mead, Jennifer
Griffith, Emily
Manea, Catherine
Bird, Jonathan
Casey, Andrew R.
Lucy
Lu
Johnston, Kathryn V.
Blanton, Michael R.
Johnson, James W.
Jablonska, Maja
Carigi, Leticia
Fernández-Trincado, José G.
Valdivia, Ricardo López
Song, Ying-Yi
Kollmeier, Juna
Astrophysics of Galaxies
The element abundances of Milky Way disc stars encode entangled imprints of multiple enrichment processes, making it difficult to uncover the underlying chemical evolution. Here we re-project 16 stellar abundances for 199,290 red giant stars ([Fe/H]$ > -1$) into a set of (4) shared enrichment patterns, providing a generative framework for learning the organising structure of the Milky Way disc. The relative contributions of these patterns vary systematically across the disc, revealing a low-dimensional enrichment basis that responds coherently to global drivers of disc evolution. By grouping stars according to their pattern contributions, we identify coherent enrichment pathways that exhibit strong chemo-spatial correlations and are stratified in both age and height above the plane, linking radial growth to vertical disc structure. Stars occupying similar positions along these enrichment pathways also show coherent vertical deviations across radius, indicating that the low-dimensional chemical structure captures the disc's response to dynamical perturbations. We identify a transition in enrichment behaviour at approximately 6 Gyr, marking the onset of a more chemically mixed regime with increasing contributions from delayed sources. Within this connected system, the observed $α$-bimodality arises within a shared, low-dimensional abundance structure, with stars populating continuous sequences of changing enrichment fractions that are tightly coupled to spatial, temporal, and orbital coordinates across the Milky Way disc.
title Milky Way Mapper decoded abundances -- II: From patterns to paths
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2605.21735