Black Holes on FIRE: Stellar Feedback Limits Early Feeding of Galactic Nuclei

TL;DR

This study uses high-resolution cosmological simulations to show that stellar feedback in early galaxies limits black hole growth, affecting their evolution and the development of active galactic nuclei.

Contribution

It introduces a novel simulation approach modeling stellar feedback and black hole growth without feedback, revealing how stellar feedback regulates early black hole accretion.

Findings

Early black hole growth occurs in short, Eddington-limited episodes.

Bursty stellar feedback evacuates gas, suppressing black hole growth in early stages.

Black holes rapidly align with scaling relations once host galaxies reach a certain mass.

Abstract

We introduce massive black holes (BHs) in the Feedback In Realistic Environments project and perform high-resolution cosmological hydrodynamic simulations of quasar-mass halos ($M_{\rm halo}(z=2) \approx 10^{12.5}\,\rm{M}_{\odot}$) down to $z=1$. These simulations model stellar feedback by supernovae, stellar winds, and radiation, and BH growth using a gravitational torque-based prescription tied to resolved properties of galactic nuclei. We do not include BH feedback. We show that early BH growth occurs through short ($\lesssim 1\,$Myr) accretion episodes that can reach or even exceed the Eddington rate. In this regime, BH growth is limited by bursty stellar feedback continuously evacuating gas from galactic nuclei, and BHs remain under-massive relative to the local $M_{\rm BH}$-$M_{\rm bulge}$ relation. BH growth is more efficient at later times, when the nuclear stellar potential retains a significant gas reservoir, star formation becomes less bursty, and galaxies settle into a more ordered state, with BHs rapidly converging onto the scaling relation when the host reaches $M_{\rm bulge} \sim 10^{10}\,\rm{M}_{\odot}$. Our results are not sensitive to the details of the accretion model so long as BH growth is tied to the gas content within $\sim 100\,$pc of the BH. Our simulations imply that bursty stellar feedback has strong implications for BH and AGN demographics, especially in the early Universe and for low-mass galaxies.