Photon Trapping Enables Super-Eddington Growth of Black-Hole Seeds in Galaxies at High Redshift

TL;DR

This paper proposes a photon trapping mechanism at high redshift that enables rapid, super-Eddington growth of seed black holes, potentially explaining the early formation of supermassive black holes in galaxies.

Contribution

It introduces a physical model of photon trapping that allows super-Eddington accretion in early galaxies, a novel explanation for rapid black hole growth.

Findings

Photon trapping occurs in black holes of 10^3-10^5 solar masses at high redshift.

Super-Eddington accretion rates are possible due to photon trapping in early galaxies.

X-ray counts at z>6 should show a cutoff below certain luminosities.

Abstract

We identify a physical mechanism that would have resulted in rapid, obscured growth of seed super-massive black-holes in galaxies at z>6. Specifically, we find that the density at the centre of typical high redshift galaxies was at a level where the Bondi accretion rate implies a diffusion speed of photons that was slower than the gravitational infall velocity, resulting in photons being trapped within the accretion flow and advected into the black-hole. We show that there is a range of black-hole masses (M_bh ~ 10^3-10^5 solar masses) where the accretion flow traps radiation, corresponding to black-holes that were massive enough to generate a photon trapping accretion flow, but small enough that their Bondi radii did not exceed the isothermal scale height of self-gravitating gas. Under these conditions we find that the accretion reaches levels far in excess of the Eddington rate. A prediction of this scenario is that X-ray number counts of active galactic nuclei at z>6 would exhibit a cutoff at the low luminosities corresponding to black-hole masses below ~10^5 solar masses. At low redshifts we find photon trapping to be unimportant because it could only occur in rare low spin halos, and would require black-hole masses in excess of expectations from the observed black-hole - halo mass relation. The super-Eddington growth of ~10^5 solar mass seed black-holes at high redshift may have provided a natural acceleration towards the growth of super-massive black-holes at z~6-7, less than a billion years after the Big Bang.