The Evolution of the Baryons Associated with Galaxies Averaged over Cosmic Time and Space
Fabian Walter, Chris Carilli, Marcel Neeleman, Roberto Decarli, Gergö Popping, Rachel S. Somerville, Manuel Aravena, Frank Bertoldi, Leindert Boogaard, Pierre Cox, Elisabete da Cunha, Benjamin Magnelli, Danail Obreschkow, Dominik Riechers, Hans-Walter Rix, Ian Smail, Axel Weiss, Roberto J. Assef, Franz Bauer, Rychard Bouwens, Thierry Contini, Paulo C. Cortes, Emanuele Daddi, Tanio Diaz-Santos, Jorge González-López, Joseph Hennawi, Jacqueline A. Hodge, Hanae Inami, Rob Ivison, Pascal Oesch, Mark Sargent, Paul van der Werf, Jeff Wagg, L. Y. Aaron Yung
Abstract
We combine the recent determination of the evolution of the cosmic density of molecular gas (H 2 ) using deep, volumetric surveys, with previous estimates of the cosmic density of stellar mass, star formation rate and atomic gas (H i ), to constrain the evolution of baryons associated with galaxies averaged over cosmic time and space. The cosmic H i and H 2 densities are roughly equal at z ∼ 1.5. The H 2 density then decreases by a factor to today’s value, whereas the H i density stays approximately constant. The stellar mass density is increasing continuously with time and surpasses that of the total gas density (H i and H 2 ) at redshift z ∼ 1.5. The growth in stellar mass cannot be accounted for by the decrease in cosmic H 2 density, necessitating significant accretion of additional gas onto galaxies. With the new H 2 constraints, we postulate and put observational constraints on a two-step gas accretion process: (i) a net infall of ionized gas from the intergalactic/circumgalactic medium to refuel the extended H i reservoirs, and (ii) a net inflow of H i and subsequent conversion to H 2 in the galaxy centers. Both the infall and inflow rate densities have decreased by almost an order of magnitude since z ∼ 2. Assuming that the current trends continue, the cosmic molecular gas density will further decrease by about a factor of two over the next 5 Gyr, the stellar mass will increase by approximately 10%, and cosmic star formation activity will decline steadily toward zero, as the gas infall and accretion shut down.