The Black Hole Mass Function Across Cosmic Times II. Heavy Seeds and (Super)Massive Black Holes

TL;DR

This paper models the evolution of supermassive black hole mass functions across cosmic time, emphasizing seed formation and growth mechanisms validated against observational data, and reconstructs the entire black hole mass spectrum.

Contribution

It introduces an ab-initio semi-empirical model for black hole growth, combining seed formation via dynamical friction and accretion, validated against observations, and reconstructs the full black hole mass spectrum.

Findings

Reproduces observed AGN luminosity functions across redshifts.

Derives relic supermassive black hole mass functions consistent with observations.

Reconstructs the black hole mass function over ten orders of magnitude.

Abstract

This is the second paper in a series aimed at modeling the black hole (BH) mass function, from the stellar to the (super)massive regime. In the present work we focus on (super)massive BHs and provide an ab-initio computation of their mass function across cosmic times. We consider two main mechanisms to grow the central BH, that are expected to cooperate in the high-redshift star-forming progenitors of local massive galaxies. The first is the gaseous dynamical friction process, that can cause the migration toward the nuclear regions of stellar-mass BHs originated during the intense bursts of star formation in the gas-rich host progenitor galaxy, and the buildup of a central heavy BH seed $M_\bullet\sim 10^{3-5}\, M_\odot$ within short timescales $\lesssim$ some $10^7$ yr. The second mechanism is the standard Eddington-type gas disk accretion onto the heavy BH seed, through which the central BH can become (super)massive $M_\bullet\sim 10^{6-10}\, M_\odot$ within the typical star-formation duration $\lesssim 1$ Gyr of the host. We validate our semi-empirical approach by reproducing the observed redshift-dependent bolometric AGN luminosity functions and Eddington ratio distributions, and the relationship between the star-formation and the bolometric luminosity of the accreting central BH. We then derive the relic (super)massive BH mass function at different redshifts via a generalized continuity equation approach, and compare it with present observational estimates. Finally, we reconstruct the overall BH mass function from the stellar to the (super)massive regime, over more than ten orders of magnitudes in BH mass.