Two Conditions for Galaxy Quenching: Compact Centres and Massive Haloes

Abstract

We investigate the roles of two classes of quenching mechanisms for central and satellite galaxies in the SDSS (z<0.075): those involving the halo and those involving the formation of a compact centre. For central galaxies with inner compactness 1kpc 109-9.4M kpc-2, the quenched fraction fq is strongly correlated with 1kpc with only weak halo mass M h dependence. However, at higher and lower 1kpc, sSFR is a strong function of M h and mostly independent of 1kpc. In other words, 1kpc 109-9.4 M kpc-2 divides galaxies into those with high sSFR below and low sSFR above this range. In both the upper and lower regimes, increasing M h shifts the entire sSFR distribtuion to lower sSFR without a qualitative change in shape. This is true even at fixed M*, but varying M* at fixed M h adds no quenching information. Most of the quenched centrals with M h > 1011.8M are dense ( 1kpc > 109~ M kpc-2), suggesting compaction-related quenching maintained by halo-related quenching. However, 21% are diffuse, indicating only halo quenching. For satellite galaxies in the outskirts of halos, quenching is a strong function of compactness and a weak function of host M h. In the inner halo, M h dominates quenching, with 90\% of the satellites being quenched once M h > 1013M. This regional effect is greatest for the least massive satellites. As demonstrated via semi-analytic modelling with simple prescriptions for quenching, the observed correlations can be explained if quenching due to central compactness is rapid while quenching due to halo mass is slow.