Impact of dust cooling on direct collapse black hole formation

Abstract

Observations of quasars at z > 6 suggest the presence of black holes with a few times 109 ~M. Numerous models have been proposed to explain their existence including the direct collapse which provides massive seeds of 105~M. The isothermal direct collapse requires a strong Lyman-Werner flux to quench H2 formation in massive primordial halos. In this study, we explore the impact of trace amounts of metals and dust enrichment. We perform three dimensional cosmological simulations for two halos of > 107~M with Z/Z= 10-4-10-6 illuminated by an intense Lyman Werner flux of J21=105. Our results show that initially the collapse proceeds isothermally with T 8000 K but dust cooling becomes effective at densities of 108-1012 ~cm-3 and brings the gas temperature down to a few 100-1000 K for Z/Z ≥ 10-6. No gravitationally bound clumps are found in Z/Z ≤ 10-5 cases by the end of our simulations in contrast to the case with Z/Z = 10-4. Large inflow rates of ≥ 0.1~M/yr are observed for Z/Z ≤ 10-5 similar to a zero-metallicity case while for Z/Z = 10-4 the inflow rate starts to decline earlier due to the dust cooling and fragmentation. For given large inflow rates a central star of 104~M may form for Z/Z ≤ 10-5.