Statistical properties of mass, star formation, chemical content and rotational patterns in early z > 9 structures

Abstract

We study the baryonic, chemical and dynamical properties of a significantly large sample of early proto-galaxies in the first 500 Myr of the Universe (redshift z>9), obtained from high-resolution numerical, N-body, hydrodynamical, chemistry simulations including atomic and molecular networks, gas cooling, star formation, stellar evolution and metal spreading for population III and population II-I regimes according to proper stellar yields and lifetimes. We find that first star formation events take place in halos with dark-matter mass MDM > 2× 106 Msun. Early star forming objects have: molecular fractions from xmol < 10-4 in quiescent structures up to xmol > 0.1 in active regions; star formation rates SFR ~10-8-10-3Msun/yr; and metallicities in the range ~10-8-10-2Zsun. Roughly ~10% of high-z haloes host population II-I star formation and dominate the cosmic SFR density. They usually are bursty objects with mean specific SFR around ~10 Gyr-1 at z~9 and increasing with redshift up to ~102 Gyr-1. Stellar feedback effects alter the baryonic content of the haloes and locally affect their chemical and thermo-dynamical properties, as reflected by the broadening of various physical relations. The establishment of gaseous rotationally-supported cores is quite uncommon, weakly related to the large-scale dark-matter behaviour and evolving in an intermittent fashion. The colder, molecular-rich phase tends to maintain any established rotational motion longer with respect to the hotter, metal-rich component, which is very sensitive to environmental processes. While the fraction of haloes featuring a significant amount of co-rotating, molecular-rich gas increases with cosmic time (from a few percent at z~20 up to ~5-15% at z~9), the chaotic nature of metal-enriched material does not lead to particular trends.