Cosmic quenching and scaling laws for the evolution of supermassive black holes and host galaxies

Abstract

Observations suggest an SMBH-host coevolution. We consider the mass and energy flow in a bulge suffused by gases of varying temperatures. By assuming the rate of energy flow independent of the distance from the bulge center and the local virial equilibrium for permeated gases, a key parameter b was identified that quantifies the rate of mass and energy flow in gases and the efficiency of gas cooling and thus regulates the coevolution of SMBHs and hosts. Using Illustris simulations, we found b (1+z)5/2. A higher b in the early Universe means a more efficient gas cooling that allows initial rapid growth of SMBHs and hosts. This simple theory, characterized by b, provides the dominant mean cosmic evolution of SMBHs and hosts. All other transient phenomena may only contribute to the dispersion around mean evolution. Relevant scaling laws involving b were identified. For host galaxies, the mass-size relation Mb b2/3rb5/3G-1, dispersion-size relation σb2(b rb)2/3 (1+z), or the mass-dispersion relation Mb b-1G-1σb5 were identified, where size rb (1+z)-1. For SMBHs, three evolution phases were found involving an initial rapid growth stage with a rising luminosity LB (b MBH)4/5, a transition stage with a declining LB b2 MBH (1+z)5, and a dormant stage with LB (b MBH)4/3. Results suggest a rapid initial super-Eddington growth with a new redshift-dependent luminosity limit LXb4/5MBH4/5G-1/5c, in contrast to the Eddington limit. Analytical solutions are formulated for the BH and AGN mass functions and AGN duty cycle and predict a slope of -1/5 for the faint-end luminosity function.