Light or heavy supermassive black hole seeds: the role of internal rotation in the fate of supermassive stars

Abstract

Supermassive black holes are a key ingredient of galaxy evolution. However, their origin is still highly debated. In one of the leading formation scenarios, a black hole of 100 M results from the collapse of the inner core of a supermassive star ( 104-5 M), created by the rapid accumulation ( 0.1 M yr-1) of pristine gas at the centre of newly formed galaxies at z 15. The subsequent evolution is still speculative: the remaining gas in the supermassive star can either directly plunge into the nascent black hole, or part of it can form a central accretion disc, whose luminosity sustains a surrounding, massive, and nearly hydrostatic envelope (a system called a "quasi-star"). To address this point, we consider the effect of rotation on a quasi-star, as angular momentum is inevitably transported towards the galactic nucleus by the accumulating gas. Using a model for the internal redistribution of angular momentum that qualitative matches results from simulations of rotating convective stellar envelopes, we show that quasi-stars with an envelope mass greater than a few 105 M × ( black~hole~mass/100 M)0.82 have highly sub-keplerian gas motion in their core, preventing gas circularisation outside the black hole's horizon. Less massive quasi-stars could form but last for only 104 years before the accretion luminosity unbinds the envelope, suppressing the black hole growth. We speculate that this might eventually lead to a dual black hole seed population: (i) massive (>104 M) seeds formed in the most massive (> 108 M) and rare haloes; (ii) lighter ( 102 M) seeds to be found in less massive and therefore more common haloes.