Rapid growth of black holes accompanied with hot or warm outflows exposed to anisotropic super-Eddington radiation

Abstract

We perform two-dimensional radiation hydrodynamical simulations of accretion flows onto a black hole (BH) with a mass of 103≤ M BH/M 106 in order to study rapid growth of BHs in the early Universe. For spherically symmetric flows, hyper-Eddington accretion onto the BH from outside the Bondi radius can occur unimpeded by radiation feedback only when the BH mass is higher than 104~M(n∞/105~ cm-3)-1(T∞/104~ K)3/2, where n∞ and T∞ are the density and temperature of ambient gas. Here, we study the properties of accretion flows exposed to anisotropic radiation from a nuclear accretion disk with a luminosity higher than the Eddington value (L Edd) due to collimation toward the bipolar directions. We find that, unlike the spherically symmetric case, even less massive BHs with M BH < 104~M can be fed by surrounding gas at high accretion rates of L Edd/c2 through the equatorial plane, while ionized regions expand to the polar directions producing hot outflows with T 105K. For more massive BHs with M BH 5× 105~M, neutral gas through the equatorial plane totally covers the central radiating region due to the non-radial gas motions, and thus the emergent radiation in all directions is blocked. Because of efficient recombination by hydrogen, the entire flow results in neutral and warm gas with T 8000~ K . The central BH is fed through the equator at the averaged rate of 5× 104~L Edd/c2, which corresponds to 50~\% of the inflow rate from the Bondi radius. Moreover, radiation momentum absorbed by neutral hydrogen produces warm outflows toward the bipolar directions at 30~\% of the BH feeding rate and with a typical velocity of 50~ km~s-1.