Halo Abundance and Assembly History with Extreme-Axion Wave Dark Matter at z 4

Abstract

Wave dark matter ( DM) composed of extremely light bosons (m 10-22\, eV), with quantum pressure suppressing structures below a kpc-scale de Broglie wavelength, has become a viable dark matter candidate. Compared to the conventional free-particle DM ( FP DM), the extreme-axion DM model ( EA DM) proposed by Zhang & Chiueh (2017) features a larger cut-off wavenumber and a broad spectral bump in the matter transfer function. Here we conduct cosmological simulations to compare the halo abundances and assembly histories at z=4-11 between three different scenarios: FP DM, EA DM, and cold dark matter (CDM). We show that EA DM produces significantly more abundant low-mass haloes than FP DM with the same m, and therefore could alleviate the tension in m required by the Lyα forest data and by the kpc-scale dwarf galaxy cores. We also find that, compared to the CDM counterparts, massive EA DM haloes are on average 3-4 times more massive at z=10-11 due to their earlier formation, undergo a slower mass accretion at 7 z 11, and then show a rapidly rising major merger rate exceeding CDM by 50\% at 4 z 7. This fact suggests that EA DM haloes may exhibit more prominent starbursts at z 7.