Confronting predictions of the galaxy stellar mass function with observations at high-redshift

Abstract

We investigate the evolution of the galaxy stellar mass function at high-redshift (z 5) using a pair of large cosmological hydrodynamical simulations: MassiveBlack and MassiveBlack-II. By combining these simulations we can study the properties of galaxies with stellar masses greater than 108\, M\,h-1 and (co-moving) number densities of 10(φ\, [ Mpc-3\,dex-1\,h3])>-8. Observational determinations of the galaxy stellar mass function at very-high redshift typically assume a relation between the observed UV luminosity and stellar mass-to-light ratio which is applied to high-redshift samples in order to estimate stellar masses. This relation can also be measured from the simulations. We do this, finding two significant differences with the usual observational assumption: it evolves strongly with redshift and has a different shape. Using this relation to make a consistent comparison between galaxy stellar mass functions we find that at z=6 and above the simulation predictions are in good agreement with observed data over the whole mass range. Without using the correct UV luminosity and stellar mass-to-light ratio, the discrepancy would be up to two orders of magnitude for large galaxies >1010\, M\,h-1. At z=5, however the stellar mass function for low mass <109\, M\,h-1 galaxies is overpredicted by factors of a few, consistent with the behaviour of the UV luminosity function, and perhaps a sign that feedback in the simulation is not efficient enough for these galaxies.