http://arxiv.org/abs/1408.2553
We re-examine the fraction of low redshift SDSS satellites and centrals in which star formation has been quenched, using the environment quenching efficiency formalism that separates out the dependence of stellar mass. We show that the centrals of the groups containing the satellites are responding to the environment in the same way as their satellites, and that the well known differences between satellites and the general set of centrals arises because the latter are overwhelmingly dominated by isolated galaxies. The widespread concept of “satellite quenching” as the cause of environmental effects in the galaxy population can therefore be generalized to “group quenching”. We then explore the dependence of the quenching efficiency of satellites on overdensity, group-centric distance, halo mass, the stellar mass of the satellite, and the stellar mass and sSFR of its central, trying to isolate the effect of these often interdependent variables. We emphasize the importance of the central sSFR in the quenching efficiency of the associated satellites, and develop the meaning of this “galactic conformity” effect in a probabilistic description of the quenching of galaxies. We show that conformity is strong, and that it varies strongly across parameter space. Several arguments then suggest that environmental quenching and mass quenching may be different manifestations of the same underlying process. These include the fact that mass quenching of galaxies is associated with the same halo masses that apparently see the onset of environmental effects in the satellites. The marked difference in the apparent mass dependencies of environment quenching and mass quenching which produces distinctive signatures in the mass functions of centrals and satellites will arise naturally, since the distribution of the environmental variables are essentially independent of the stellar mass of the satellite.
C. Knobel, S. Lilly, J. Woo, et. al.
Wed, 13 Aug 14
25/57
Comments: 22 pages, 11 figures, submitted to ApJ
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