HOW RAPIDLY DO SUPERMASSIVE BLACK HOLE 'SEEDS' GROW AT EARLY TIMES?

摘要

We investigate the physical conditions for the growth of intermediate-mass seed black holes assumed to have formed from remnants of the first generation of massive stars. We follow the collapse of high σ halos with T_(vir) ＞ 10~4 K using cosmological, smooth-particle hydrodynamic (SPH) simulations in the standard ACDM model. During the collapse of the parent halo, the seed holes are incorporated through mergers into larger systems and accrete mass from the surrounding gas. We include a self-consistent treatment of star formation, black hole accretion, and associated feedback processes. Even under optimistic assumptions for the seed black hole mass and for efficient merger rates, we find that seed holes in halos M ≤ 10~(10) solar mass never reach the conditions for critical Eddington growth. Most of the black hole growth in this regime is determined by the initial mass and the merger rates. Critical accretion rates are reached, albeit only after a significant delay, at the time of collapse (z ～ 7) for 3-4 σ halos of M ～ 10~(11) solar mass. Our results imply M_(BH) = 5 × 10~6 solar mass(M_(halo)/10~(11) solar mass)~(0.78) at the time of collapse. The required conditions of Eddington growth to explain the buildup of supermassive black holes ( ～ 10~9 solar mass), as implied by Sloan quasars at z ＞ 6, are therefore hard to meet in such a scenario. Without a "jump start," these conditions may be only achieved in extremely rare halos with M_(halo) ＞ 10~(13) that collapsed before z ～ 6. The sub-Eddington regime in which black holes accrete at early time implies a small contribution to the reionization by miniquasar but still sufficient to cause appreciable heating of the IGM at z approx ＜ 15-18.