A Turnover in the Galaxy Main Sequence of Star Formation at M* 1010 M for Redshifts z < 1.3

Abstract

The relationship between galaxy star formation rates (SFR) and stellar masses (M) is re-examined using a mass-selected sample of 62,000 star-forming galaxies at z 1.3 in the COSMOS 2-deg2 field. Using new far-infrared photometry from Herschel-PACS and SPIRE and Spitzer-MIPS 24 μm, along with derived infrared luminosities from the NRK method based on galaxies' locations in the restframe color-color diagram (NUV - r) vs. (r - K), we are able to more accurately determine total SFRs for our complete sample. At all redshifts, the relationship between median SFR and M follows a power-law at low stellar masses, and flattens to nearly constant SFR at high stellar masses. We describe a new parameterization that provides the best fit to the main sequence and characterizes the low mass power-law slope, turnover mass, and overall scaling. The turnover in the main sequence occurs at a characteristic mass of about M0 1010 M at all redshifts. The low mass power-law slope ranges from 0.9-1.3 and the overall scaling rises in SFR as a function of (1+z)4.12 0.10. A broken power-law fit below and above the turnover mass gives relationships of SFR M*0.88 0.06 below the turnover mass and SFR M*0.27 0.04 above the turnover mass. Galaxies more massive than M 1010\ M have on average, a much lower specific star formation rate (sSFR) than would be expected by simply extrapolating the traditional linear fit to the main sequence found for less massive galaxies.