We examine galaxy star formation rates (SFRs), metallicities and gas contents predicted by the MUFASA cosmological hydrodynamic simulations, which employ meshless hydrodynamics and novel feedback prescriptions that yield a good match to observed galaxy stellar mass assembly. We combine 50, 25 and 12.5 h(-1) Mpc boxes with a quarter billion particles each to show that MUFASA broadly reproduces a wide range of relevant observations, including SFR and specific SFR functions, the mass-metallicity relation, HI and H-2 fractions, HI (21 cm) and CO luminosity functions, and cosmic gas density evolution. There are mild but significant discrepancies, such as perhaps too many high-SFR galaxies, overly metal-rich and HI-poor galaxies at M-* greater than or similar to 2 x 10(10)M(circle dot), and specific star formation rates that are too low at z similar to 1-2. The HI mass function increases by x2 out to z similar to 1, then steepens to higher redshifts, while the CO luminosity function computed using the Narayanan et al. conversion factor shows a rapid increase of CO-bright galaxies out to z similar to 2 in accord with data. Omega HI and Omega H-2 both scale roughly as proportional to(1 + z) (0.7) out to z similar to 3, comparable to the rise in HI and H-2 fractions. MUFASA galaxies with high SFR at a given M-* have lower metallicities and higher HI and H-2 fractions, following observed trends; we make quantitative predictions for how the fluctuations in the baryon cycle drive correlated scatter around galaxy scaling relations. Most of these trends are well converged with numerical resolution. These successes highlight MUFASA as a viable platform to study many facets of cosmological galaxy evolution.

• 出版日期2017-5