NeutralUniverseMachine: An Empirical Model for the Evolution of HI and H2 Gas in the Universe

Abstract

Accurately modeling the cold gas content in the universe is challenging for current theoretical models. We propose a new empirical model NeutralUniverseMachine for the evolution of HI and H2 gas along with dark matter halos based on the UniverseMachine catalog. It is able to accurately describe the observed HI and H2 mass functions, molecular-to-atomic ratio, HI-halo mass relation, HI/H2-stellar mass relations at z0, as well as the evolution of cosmic gas densities HI and H2 in 0<z<6. The predictions from our model include: (i) There is weak evolution of HI mass function in 0<z<3, but the evolution of H2 mass function is much stronger at the massive end. (ii) The average HI and H2 masses at a given stellar mass decrease by around 1 dex since z=3 for the star-forming galaxies, but the evolution for the quenched galaxies is much weaker. (iii) Star-forming galaxies have varying HI depletion time τ HI from 0.1 Gyr to 10 Gyr, and the dependence of τ HI on stellar mass and redshift is much stronger than those of H2 depletion time. The quenched galaxies have much longer gas depletion time and weaker redshift evolution. (iv) The cosmic baryon density associated with galaxies is dominated by stars for z<1.2 and mainly contributed by HI gas at higher redshifts. (v) The HI bias gradually increases with the redshift from 0.69 to 2.33 in 0<z<3 and is consistent with recent HI intensity mapping experiments.