From the first stars to the first black holes

TL;DR

This study explores the origins of the first supermassive black holes at high redshift, comparing the roles of light and heavy seed black holes through cosmological simulations, highlighting the conditions favoring heavy seed formation.

Contribution

It demonstrates that a few heavy seeds are crucial for SMBH growth at z > 6, emphasizing the importance of feedback effects and seed formation conditions.

Findings

Heavy seeds enable SMBH growth at high redshift.

Formation of heavy seeds depends on feedback and metallicity conditions.

Light seed contribution varies with their initial mass range.

Abstract

The growth of the first super massive black holes (SMBHs) at z > 6 is still a major challenge for theoretical models. If it starts from black hole (BH) remnants of Population III stars (light seeds with mass ~ 100 Msun) it requires super-Eddington accretion. An alternative route is to start from heavy seeds formed by the direct collapse of gas onto a ~ 10^5 Msun BH. Here we investigate the relative role of light and heavy seeds as BH progenitors of the first SMBHs. We use the cosmological, data constrained semi-analytic model GAMETE/QSOdust to simulate several independent merger histories of z > 6 quasars. Using physically motivated prescriptions to form light and heavy seeds in the progenitor galaxies, we find that the formation of a few heavy seeds (between 3 and 30 in our reference model) enables the Eddington-limited growth of SMBHs at z > 6. This conclusion depends sensitively on the interplay between chemical, radiative and mechanical feedback effects, which easily erase the conditions that allow the suppression of gas cooling in the low metallicity gas (Z < Zcr and JLW > Jcr). We find that heavy seeds can not form if dust cooling triggers gas fragmentation above a critical dust-to-gas mass ratio (D > Dcr). In addition, the relative importance of light and heavy seeds depends on the adopted mass range for light seeds, as this dramatically affects the history of cold gas along the merger tree, by both SN and AGN-driven winds.