Witnessing the birth of a supermassive protostar

Abstract

The detection of z>6 quasars reveals the existence of supermassive black holes of a few 109~M. One of the potential pathways to explain their formation in the infant universe is the so-called direct collapse model which provides massive seeds of 105-106~M. An isothermal direct collapse mandates that halos should be of a primordial composition and the formation of molecular hydrogen remains suppressed in the presence of a strong Lyman Werner flux. In this study, we perform high resolution cosmological simulations for two massive primordial halos employing a detailed chemical model which includes H- cooling as well as realistic opacities for both the bound-free H- emission and the Rayleigh scattering of hydrogen atoms. We are able to resolve the collapse up to unprecedentedly high densities of 10-3~g/cm3 and to scales of about 10-4 AU. Our results show that the gas cools down to 5000 K in the presence of H- cooling, and induces fragmentation at scales of about 8000 AU in one of the two simulated halos, which may lead to the formation of a binary. In addition, fragmentation also occurs on the AU scale in one of the halos but the clumps are expected to merge on short time scales. Our results confirm that H- cooling does not prevent the formation of a supermassive star and the trapping of cooling radiation stabilises the collapse on small scales.