The comoving infrared luminosity density: domination of cold galaxies across 0 < z < 1

sIn this paper, we examine the contribution of galaxies with different infrared (IR) spectral energy distributions (SEDs) to the comoving IR luminosity density (IRLD), a proxy for the comoving star formation rate (SFR) density. We characterize galaxies as having either a cold or hot IR SED depending on whether the rest-frame wavelength of their peak IR energy output is above or below 90 mu m. Our work is based on a far-IR selected sample both in the local Universe and at high redshift, the former consisting of IRAS 60 mu m-selected galaxies at z < 0.07 and the latter of Spitzer 70 mu m selected galaxies across 0.1 < z <= 1. We find that the total IR luminosity densities for each redshift/luminosity bin agree well with results derived from other deep mid-/far-IR surveys. At z < 0.07, we observe the previously known results that moderate luminosity galaxies (L-IR < 10(11) L-circle dot) dominate the total luminosity density and that the fraction of cold galaxies decreases with increasing luminosity, becoming negligible at the highest luminosities. Conversely, above z = 0.1, we find that luminous IR galaxies (L-IR > 10(11) L-circle dot), the majority of which are cold, dominate the IRLD. We therefore infer that cold galaxies dominate the IRLD across the whole 0 < z < 1 range, hence appear to be the main driver behind the increase in SFR density up to z similar to 1 whereas local luminous galaxies are not, on the whole, representative of the high-redshift population.