Simulating the growth of Intermediate Mass Black Holes

Abstract

Theoretical models predict that a population of Intermediate Mass Black Holes (IMBHs) of mass M ≈ 104-5 \, M might form at high (z > 10) redshift by different processes. Such objects would represent the seeds out of which z > 6 Super-Massive Black Holes (SMBHs) grow. We numerically investigate the radiation-hydrodynamic evolution governing the growth of such seeds via accretion of primordial gas within their parent dark matter halo of virial temperature Tvir 104 \, K. We find that the accretion onto a Direct Collapse Black Hole (DCBH) of initial mass M0=105 \, M occurs at an average rate M 1.35 \, MEdd 0.1 \, M \, yr-1, is intermittent (duty-cycle < 50\%) and lasts ≈ 142 \, Myr; the system emits on average at super-Eddington luminosities, progressively becoming more luminous as the density of the inner mass shells, directly feeding the central object, increases. Finally, when ≈ 90\% of the gas mass has been accreted (in spite of an average super-Eddington emission) onto the black hole, whose final mass is 7 × 106 \, M, the remaining gas is ejected from the halo due to a powerful radiation burst releasing a peak luminosity Lpeak 3× 1045 \, erg \, s-1. The IMBH is Compton-thick during most of the evolution, reaching a column density NH 1025 \, cm-2 in the late stages of the simulation. We briefly discuss the observational implications of the model.