The Critical Mass in Galaxy Evolution
Abstract
We investigate the physical origin of critical mass, a threshold where many galaxy properties and scaling relations undergo fundamental transitions, using the Horizon Run 5 simulation. Focusing on massive () central galaxies, we examine the mass-dependent turnover of the stellar-to-total mass ratio (STR) and the physical processes driving it. We decompose STR into the stellar-to-baryon mass ratio () and baryon retention fraction () to examine galaxies' ability to retain baryons and convert them into stars. We find that STR evolution is dominated by variation in , which changes by over a factor of three, peaking within a narrow range of independent of redshift, while varies by at most 30%. A redshift-independent critical mass at () arises from the changing nature of gas accretion. At this scale, a dynamically stable hot gas halo develops that suppresses cool gas inflow, reducing in-situ star formation efficiency such that growth exceeds in-situ growth. Consequently, the hot gas reservoir grows while growth slows, producing upturns in and and a downturn in that ultimately drives the STR turnover. We also identify a secondary critical mass at (or ) where gas retention fraction peaks, above which increasing hot gas fraction gradually suppresses in-situ star formation efficiency.
Cite
@article{arxiv.2604.27477,
title = {The Critical Mass in Galaxy Evolution},
author = {Preetish K. Mishra and Changbom Park and Jaehyun Lee and Yohan Dubois and Christophe Pichon and Juhan Kim and Brad Gibson},
journal= {arXiv preprint arXiv:2604.27477},
year = {2026}
}
Comments
14 pages, 9 figures. Comments welcome