Predictions for the Abundance of High-redshift Galaxies in a Fuzzy Dark Matter Universe

Abstract

During the last decades, rapid progress has been made in measurements of the rest-frame ultraviolet (UV) luminosity function (LF) for high-redshift galaxies (z ≥ 6). The faint-end of the galaxy LF at these redshifts provides powerful constraints on different dark matter models that suppress small-scale structure formation. In this work we perform full hydrodynamical cosmological simulations of galaxy formation using an alternative DM model composed of extremely light bosonic particles (m 10-22 eV), also known as fuzzy dark matter (FDM), and examine the predictions for the galaxy stellar mass function and luminosity function at z ≥ 6 for a range of FDM masses. We find that for FDM models with bosonic mass m = 5×10-22 eV, the number density of galaxies with stellar mass M* 107 M is suppressed by 40\% at z = 9, 20\% at z = 5, and the UV LFs within magnitude range of -16 < M UV < -14 is suppressed by 60\% at z = 9, 20\% at z = 5 comparing to the CDM counterpart simulation. Comparing our predictions with current measurements of the faint-end LFs (-18 ≤slant M UV ≤slant -14), we find that FDM models with m22 < 5×10-22 are ruled out at 3σ confidence level. We expect that future LF measurements by James Webb Space Telescope (JWST), which will extend down to M UV -13 for z 10, with a survey volume that is comparable to the Hubble Ultra Deep Field (HUDF) would have the capability to constrain FDM models to m\; 10-21 eV.