The Evolution of the Galaxy Stellar Mass Function at z= 4-8: A Steepening Low-mass-end Slope with Increasing Redshift

Abstract

We present galaxy stellar mass functions (GSMFs) at z= 4-8 from a rest-frame ultraviolet (UV) selected sample of 4500 galaxies, found via photometric redshifts over an area of 280 arcmin2 in the CANDELS/GOODS fields and the Hubble Ultra Deep Field. The deepest Spitzer/IRAC data yet-to-date and the relatively large volume allow us to place a better constraint at both the low- and high-mass ends of the GSMFs compared to previous space-based studies from pre-CANDELS observations. Supplemented by a stacking analysis, we find a linear correlation between the rest-frame UV absolute magnitude at 1500 \ (M UV) and logarithmic stellar mass ( M*) that holds for galaxies with (M*/M) 10. We use simulations to validate our method of measuring the slope of the M*-M UV relation, finding that the bias is minimized with a hybrid technique combining photometry of individual bright galaxies with stacked photometry for faint galaxies. The resultant measured slopes do not significantly evolve over z= 4-8, while the normalization of the trend exhibits a weak evolution toward lower masses at higher redshift. We combine the M*-M UV distribution with observed rest-frame UV luminosity functions at each redshift to derive the GSMFs, finding that the low-mass-end slope becomes steeper with increasing redshift from α=-1.55+0.08-0.07 at z=4 to α=-2.25+0.72-0.35 at z=8. The inferred stellar mass density, when integrated over M*=108-1013 M, increases by a factor of 10+30-2 between z=7 and z=4 and is in good agreement with the time integral of the cosmic star formation rate density.