The rapid growth phase of supermassive black holes

Abstract

We investigate the rapid growth phase of supermassive black holes (BHs) within the hydrodynamical cosmological simulation. This non-linear phase of BH growth occurs within * galaxies, embedded between two regulatory states of the galaxy host: in sub L* galaxies efficient stellar feedback regulates the gas inflow onto the galaxy and significantly reduces the growth of the central BH, while in galaxies more massive than L* efficient AGN feedback regulates the gas inflow onto the galaxy and curbs further non-linear BH growth. We find evolving critical galaxy and halo mass scales at which rapid BH growth begins. Galaxies in the low-redshift Universe transition into the rapid BH growth phase in haloes that are approximately an order of magnitude more massive than their high-redshift counterparts (200 ≈ 1012.4~ at z ≈ 0 decreasing to 200 ≈ 1011.2~ at z ≈ 6). Instead, BHs enter the rapid growth phase at a fixed critical halo virial temperature (Tvir ≈ 105.6~K). We additionally show that major galaxy--galaxy interactions (μ ≥ 14, where μ is the stellar mass ratio) play a substantial role in triggering the rapid growth phase of BHs in the low-redshift Universe, whilst potentially having a lower influence at high redshift. Approximately 40\% of BHs that initiate the rapid BH growth phase at z ≈ 0 do so within 0.5 dynamical times of a major galaxy--galaxy merger, a fourfold increase above what is expected from the background merger rate. We find that minor mergers (110 ≤ μ < 14) have a substantially lower influence in triggering the rapid growth phase at all epochs.