UV regulated star formation in high-redshift galaxies

The first galaxies forming a few hundred million years after the big bang are the key drivers of cosmic evolution and ideal laboratories to study theories of galaxy formation. We here study the role of UV radiation in suppressing star formation in primordial galaxies by destroying molecular hydrogen, the main coolant in primordial gas, and provide estimates of cold dense gas at the onset of star formation. To accomplish this goal, we perform three-dimensional cosmological simulations of minihaloes in different environments forming at z similar to 25 by varying strength of background UV flux below the Lyman limit between 0.01-1000 in units of J(21) = 10(-21) erg cm(-2) s(-1) Hz(-1) sr(-1). Particularly, we include photodetachment of H-, the self-shielding of H-2, which both were neglected in previous studies and use updated reaction rates. Our results show that depending on the background level H-2 formation is suppressed, delaying gravitational collapse until haloes reach the atomic cooling limit. We find that the formation of cold dense molecular gas and subsequently star formation gets delayed by 100-230 Myr depending on the level of the background radiation and the growth history of the dark matter haloes. The fraction of dense self-shielded gas is a strong function of the background flux and exponentially declines with the strength of incident UV flux above J(21) >= 1. We find that taking into account H-2 self-shielding is crucial for accurately estimating the amount of cold dense gas available for star formation.