Implications of Increased Central Mass Surface Densities for the Quenching of Low-mass Galaxies

Abstract

We use the Cosmic Assembly Deep Near-infrared Extragalactic Legacy Survey (CANDELS) data to study the relationship between quenching and the stellar mass surface density within the central radius of 1 kpc (1) of low-mass galaxies (stellar mass M* 109.5 M) at 0.5 ≤ z < 1.5. Our sample is mass complete down to 109 M at 0.5 ≤ z < 1.0. We compare the mean 1 of star-forming galaxies (SFGs) and quenched galaxies (QGs) at the same redshift and M*. We find that low-mass QGs have higher 1 than low-mass SFGs, similar to galaxies above 1010 M. The difference of 1 between QGs and SFGs increases slightly with M* at M* 1010 M and decreases with M* at M* 1010 M. The turnover mass is consistent with the mass where quenching mechanisms transition from internal to environmental quenching. At 0.5 ≤ z < 1.0, we find that the 1 of galaxies increases by about 0.25 dex in the green valley (i.e., the transitioning region from star forming to fully quenched), regardless of their M*. Using the observed specific star formation rate (sSFR) gradient in the literature as a constraint, we estimate that the quenching timescale (i.e., time spent in the transition) of low-mass galaxies is a few (4) Gyrs at 0.5 ≤ z < 1.0. The mechanisms responsible for quenching need to gradually quench star formation in an outside-in way, i.e., preferentially ceasing star formation in outskirts of galaxies while maintaining their central star formation to increase 1. An interesting and intriguing result is the similarity of the growth of 1 in the green valley between low-mass and massive galaxies, which suggests that the role of internal processes in quenching low-mass galaxies is a question worthy of further investigation.