Bulge-driven Fueling of Seed Black Holes

TL;DR

This study uses radiation-hydrodynamics simulations to explore how bulge mass influences black hole growth, revealing a critical bulge mass threshold that enables efficient accretion and impacts early galaxy evolution.

Contribution

It demonstrates that bulge gravitational potential significantly enhances black hole accretion rates, identifying a critical bulge mass for efficient growth of seed black holes.

Findings

Accretion rate scales with bulge mass when above critical threshold.

Light seed black holes cannot grow efficiently until bulge reaches critical mass.

Massive seed black holes can grow rapidly in supercritical bulges.

Abstract

We examine radiation-regulated accretion onto intermediate-mass and massive black holes (BHs) embedded in a bulge component. Using spherically symmetric one-dimensional radiation-hydrodynamics simulations, we track the growth of BHs accreting from a cold, neutral gas reservoir with temperature T=10^4 K. We find that the accretion rate of BHs embedded in bulges is proportional to r_{B,eff}/r_B, where r_{B,eff} is the increased effective Bondi radius that includes the gravitational potential of the bulge, and r_B is the Bondi radius of the BH. The radiative feedback from the BH suppresses the cold accretion rate to ~1 percent of the Bondi rate when a bulge is not considered. However, we find that the BH fueling rate increases rapidly when the bulge mass M_bulge is greater than the critical value of 10^6 M_sun and is proportional to M_bulge. Since the critical bulge mass is independent of the central BH mass M_{BH}, the growth rate of BHs with masses of 10^2, 10^4, and 10^6 M_sun exhibits distinct dependencies on the bulge-to-BH mass ratio. Our results imply that light seed BHs (<= 10^2 M_sun) which might be the remnants of the Pop III stars, cannot grow through accretion coevally with the early assembly of the bulge of the host galaxies until the bulge reaches the critical mass. However, massive BH seeds (>= 10^5 M_sun) that may form via direct collapse, are more likely to be embedded in a supercritical bulge and thus can grow efficiently coupling to the host galaxies and driving the early evolution of the M_{BH}-$\sigma$ relationship.