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 (M tot ≥ 1012 M) 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 (M*/M bar) and baryon retention fraction (M bar/M tot) to examine galaxies' ability to retain baryons and convert them into stars. We find that STR evolution is dominated by variation in M*/M bar, which changes by over a factor of three, peaking within a narrow range of M tot 1012.4--12.7 M independent of redshift, while M bar/M tot varies by at most 30%. A redshift-independent critical mass at M tot 1012.5 M (M* 1010.7 M) 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 M tot growth exceeds in-situ M* growth. Consequently, the hot gas reservoir grows while M* growth slows, producing upturns in M gas/M tot and M bar/M tot and a downturn in M*/M bar that ultimately drives the STR turnover. We also identify a secondary critical mass at M tot ≈ 1011 M (or M* ≈ 109--9.5 M) where gas retention fraction peaks, above which increasing hot gas fraction gradually suppresses in-situ star formation efficiency.