Seeding Black Holes in Cosmological Simulations

TL;DR

This paper introduces a new cosmological simulation model for black hole formation from primordial gas peaks, incorporating growth via accretion and mergers, and demonstrating consistency with key astronomical observations.

Contribution

It presents a novel black hole seeding model based on Population III star remnants, improving the realism of cosmological simulations.

Findings

Successfully reproduces cosmic star formation history

Matches observed black hole mass--velocity dispersion relation

Aligns with galaxy size--velocity dispersion observations

Abstract

We present a new model for the formation of black holes in cosmological simulations, motivated by the first star formation. Black holes form from high density peaks of primordial gas, and grow via both gas accretion and mergers. Massive black holes heat the surrounding material, suppressing star formation at the centres of galaxies, and driving galactic winds. We perform an investigation into the physical effects of the model parameters, and obtain a `best' set of these parameters by comparing the outcome of simulations to observations. With this best set, we successfully reproduce the cosmic star formation rate history, black hole mass -- velocity dispersion relation, and the size -- velocity dispersion relation of galaxies. The black hole seed mass is 10^3Msun, which is orders of magnitude smaller than has been used in previous cosmological simulations with active galactic nuclei, but suggests that the origin of the seed black holes is the death of Population III stars.