Stochastic Processes as the Origin of the Double-Power Law Shape of the Quasar Luminosity Function

Abstract

The Quasar Luminosity Function (QLF) offers insight into the early co-evolution of black holes and galaxies. It has been characterized observationally up to redshift z6 with clear evidence of a double power-law shape, in contrast to the Schechter-like form of the underlying dark-matter halo mass function. We investigate a physical origin for the difference in these distributions by considering the impact of stochasticity induced by the processes that determine the quasar luminosity for a given host halo and redshift. We employ a conditional luminosity function and construct the relation between median quasar magnitude versus halo mass MUV,c(Mh) with log-normal in luminosity scatter , and duty-cycle εDC, and focus on high redshift z4. We show that, in order to reproduce the observed QLF, the =0 abundance matching requires all of the brightest quasars to be hosted in the rarest most massive dark-matter halos (with an increasing MUV,c/Mh in halo mass). Conversely, for >0 the brightest quasars can be over-luminous outliers hosted in relatively common dark-matter halos. In this case, the median quasar magnitude versus halo mass relation, MUV,c, flattens at the high-end, as expected in self-regulated growth due to feedback. We sample the parameter space of and εDC and show that MUV,c flattens above Mh 1012M for εDC<10-2. Models with εDC1 instead require a high mass threshold close to Mh1013M. We investigate the impact of εDC and on measurements of clustering and find there is no luminosity dependence on clustering for >0.3, consistent with recent observations from Subaru HSC.