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Autores principales: McDonough, Bryanne, Iyengar, Sathvika S., Brew-Smith, Ansa, Bluck, Asa F. L., Piotrowska, Joanna
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2604.15182
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author McDonough, Bryanne
Iyengar, Sathvika S.
Brew-Smith, Ansa
Bluck, Asa F. L.
Piotrowska, Joanna
author_facet McDonough, Bryanne
Iyengar, Sathvika S.
Brew-Smith, Ansa
Bluck, Asa F. L.
Piotrowska, Joanna
contents We apply Random Forest and XGBoost machine learning algorithms to determine which galaxy properties most effectively predict star formation and quenching in simulated galaxies. Using spatially-resolved data from approximately 63,000 annular bins across 6,189 TNG100 galaxies, we train classification models to predict quenching states and regression models to predict star formation rate surface densities. Despite their different algorithmic approaches, both methods produce consistent feature importance rankings, with XGBoost distributing importance more evenly among correlated features. For central galaxies and high-mass satellites, black hole mass dominates quenching predictions, consistent with quenching via active galactic nuclei (AGN) feedback. Classification of low-mass satellites shows overwhelming importance for halo mass, indicating environmental quenching. Star formation predictions are dominated by local stellar mass surface density across all star-forming galaxy types, confirming that active star formation is a local process while quenching is driven by global properties.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15182
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Understanding the regulation of star formation within TNG100 galaxies on kpc-scales using machine learning I: Global versus local
McDonough, Bryanne
Iyengar, Sathvika S.
Brew-Smith, Ansa
Bluck, Asa F. L.
Piotrowska, Joanna
Astrophysics of Galaxies
We apply Random Forest and XGBoost machine learning algorithms to determine which galaxy properties most effectively predict star formation and quenching in simulated galaxies. Using spatially-resolved data from approximately 63,000 annular bins across 6,189 TNG100 galaxies, we train classification models to predict quenching states and regression models to predict star formation rate surface densities. Despite their different algorithmic approaches, both methods produce consistent feature importance rankings, with XGBoost distributing importance more evenly among correlated features. For central galaxies and high-mass satellites, black hole mass dominates quenching predictions, consistent with quenching via active galactic nuclei (AGN) feedback. Classification of low-mass satellites shows overwhelming importance for halo mass, indicating environmental quenching. Star formation predictions are dominated by local stellar mass surface density across all star-forming galaxy types, confirming that active star formation is a local process while quenching is driven by global properties.
title Understanding the regulation of star formation within TNG100 galaxies on kpc-scales using machine learning I: Global versus local
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2604.15182