Galaxy Stellar Mass Functions from z~10 to z~6 using the Deepest Spitzer/IRAC Data: No Significant Evolution in the Stellar-to-Halo Mass Ratio of Galaxies in the First Gyr of Cosmic Time

Abstract

We present new stellar mass functions at z6, z7, z8, z9 and, for the first time, z10, constructed from 800 Lyman-Break galaxies previously identified over the XDF/UDF, parallels and the five CANDELS fields. Our study is distinctive due to (1) the much deeper (200 hour) wide-area Spitzer/IRAC imaging at 3.6μm and 4.5μm from the GOODS Re-ionization Era wide Area Treasury from Spitzer (GREATS) program and (2) consideration of z6-10 sources over a 3× larger area than previous HST+Spitzer studies. The Spitzer/IRAC data enable 2σ rest-frame optical detections for an unprecedented 50\% of galaxies down to a stellar mass limit of 108M across all redshifts. Schechter fits to our volume densities suggest a combined evolution in characteristic mass M* and normalization factor φ* between z6 and z8. The stellar mass density (SMD) increases by 1000× in the 500 Myr between z10 and z6, with indications of a steeper evolution between z10 and z8, similar to the previously-reported trend of the star-formation rate density. Strikingly, abundance matching to the Bolshoi-Planck simulation indicates halo mass densities evolving at approximately the same rate as the SMD between z10 and z4. Our results show that the stellar-to-halo mass ratios, a proxy for the star-formation efficiency, do not change significantly over the huge stellar mass build-up occurred from z10 to z6, indicating that the assembly of stellar mass closely mirrors the build-up in halo mass in the first 1 Gyr of cosmic history. JWST is poised to extend these results into the "first galaxy" epoch at z10.