Characteristic mass in galaxy quenching: environmental versus internal effects

Abstract

A clear transition feature of galaxy quenching is identified in the multi-parameter space of stellar mass (M*), bulge to total mass ratio (B/T m), halo mass (M h) and halo-centric distance (r/r180). For given halo mass, the characteristic stellar mass (M*, ch) for the transition is about one-fifth of that of the corresponding central galaxy, and almost independent of B/T m. Once B/T m is fixed, the quenched fraction of galaxies with M* < M*, ch increases with M h, but decreases with M* in the inner part of halos (r/r180 < 0.5). In the outer part (r/r180 > 0.5), the trend with M h remains but the correlation with M* is absent or becomes positive. For galaxies above M *, ch and with B/T m fixed, the quenched fraction increases with M *, but depends only weakly on M h in both the inner and outer regions. At fixed B/T m and M*, the quenched fraction increases with decreasing r/r180 for galaxies with M* < M*, ch, and depends only weakly on r/r180 for galaxies with M* > M*, ch. Our finding provides a physically-motivated way to classify galaxies in halos into two classes based on their quenching properties: an `upper class' with M* > M *,ch and a `lower class' with M* < M *,ch. Environmental quenching is important for `lower class' galaxies, while internal quenching plays the dominating role for the `upper class'.