The effects of super-Eddington accretion and feedback on the growth of early supermassive black holes and galaxies

TL;DR

This study uses cosmological simulations to explore how super-Eddington accretion and feedback mechanisms influence the growth of early supermassive black holes and their host galaxies, revealing that super-Eddington phases significantly alter galaxy properties.

Contribution

It introduces the first detailed simulation comparison of super-Eddington accretion effects on early black hole and galaxy evolution within a cosmological context.

Findings

Super-Eddington accretion causes rapid black hole growth bursts.

Galaxies with super-Eddington black holes are more extended and less massive.

Jets have minimal impact on galaxy properties but affect black hole mass growth.

Abstract

We present results of cosmological zoom-in simulations of a massive protocluster down to redshift $z\approx4$ (when the halo mass is $\approx10^{13}$ M$_\odot$) using the SWIFT code and the EAGLE galaxy formation model, focusing on supermassive black hole (BH) physics. The BH was seeded with a mass of $10^4$ M$_\odot$ at redshift $z\approx17$. We compare the base model that uses an Eddington limit on the BH accretion rate and thermal isotropic feedback by the AGN, with one where super-Eddington accretion is allowed, as well as two other models with BH spin and jets. In the base model, the BH grows at the Eddington limit from $z=9$ to $z=5.5$, when it becomes massive enough to halt its own and its host galaxy's growth through feedback. We find that allowing super-Eddington accretion leads to drastic differences, with the BH going through an intense but short super-Eddington growth burst around $z\approx7.5$, during which it increases its mass by orders of magnitude, before feedback stops further growth (of both the BH and the galaxy). By $z\approx4$ the galaxy is only half as massive in the super-Eddington cases, and an order of magnitude more extended, with the half-mass radius reaching values of a few physical kpc instead of a few hundred pc. The BH masses in our simulations are consistent with the intrinsic BH mass$-$stellar mass relation inferred from high-redshift observations by JWST. This shows that galaxy formation models using the $\Lambda$CDM cosmology are capable of reproducing the observed massive BHs at high redshift. Allowing jets, either at super- or sub-Eddington rates, has little impact on the host galaxy properties, but leads to lower BH masses as a consequence of higher feedback efficiencies.