Must Starforming Galaxies Rapidly Get Denser Before They Quench?

Abstract

Using the deepest data yet obtained, we find no evidence preferring compaction-triggered quenching---where rapid increases in galaxy density truncate star formation---over a null hypothesis in which galaxies age at constant surface density (e M*/2π re2). Results from two fully empirical analyses and one quenching-free model calculation support this claim at all z≤3: (1) Qualitatively, galaxies' mean U-V colors at 6.5e/ M\, kpc-210 have reddened at rates/times correlated with e, implying that there is no density threshold at which galaxies turn red but that e sets the pace of maturation; (2) Quantitatively, the abundance of M*/ M≥9.4 red galaxies never exceeds that of the total population a quenching time earlier at any e, implying that galaxies need not transit from low to high densities before quenching; (3) Applying d re/dt =1/2\,d M*/dt to a suite of lognormal star formation histories reproduces the evolution of the size--mass relation at M*≥10. All results are consistent with evolutionary rates being set ab initio by global densities, with denser objects evolving faster than less-dense ones towards a terminal quiescence induced by gas depletion or other -timescale phenomena. Unless stellar ages demand otherwise, observed e thresholds need not bear any physical relation to quenching beyond this intrinsic density--formation epoch correlation, adding to Lilly & Carollo's arguments to that effect.