The first generation of star-forming haloes

We model gas cooling in high-resolution N-body simulations in order to investigate the formation of the first generation of stars. We follow a region of a Lambda cold dark matter (Lambda CDM) universe especially selected to contain a rich cluster by the present day. The properties of the dark haloes that form in these subsolar mass-resolution simulations are presented in a companion paper by Gao et al. The first gas clouds able to cool by molecular hydrogen (H-2)-line emission collapse at extremely high redshift, z approximate to 47, when the mass of the dark halo is 2.4 x 10(5) h(-1) M-circle dot. By z approximate to 30, a substantial population of haloes are capable of undergoing molecular hydrogen cooling although their ability to form stars is dependent on the efficiency of feedback processes such as dissociating Lyman-Werner radiation. The mass of the main halo grows extremely rapidly and, by z approximate to 36, its virial temperature has reached 10(4) K, at which point gas cooling becomes dominated by more effective atomic processes. By z approximate to 30, a small 'group' of such potential galaxies will have formed unless prevented from doing so by feedback processes. By this redshift, massive (greater than or similar to 100 M-circle dot) Population III stars are able to ionize gas well beyond their own host halo and neighbouring Hii regions can percolate to form an ionized superbubble. Such patches would be too widely separated to contribute significantly to reionization at this time. The large number density of early cooling haloes in the pre-reionized universe raises the exciting prospect that this ultra-early generation of stars may be observable as gamma-ray bursts or supernovae.