Dust, CO and [CI]: Cross-calibration of molecular gas mass tracers in metal-rich galaxies across cosmic time

Abstract

We present a self-consistent cross-calibration of the three main molecular gas mass tracers in galaxies, the 12CO(1-0), [CI](3P1-3P0) lines, and the submm dust continuum emission, using a sample of 407 galaxies, ranging from local disks to submillimetre-selected galaxies (SMGs) up to z ≈ 6. A Bayesian method is used to produce galaxy-scale universal calibrations of these molecular gas indicators, that hold over 3-4 orders of magnitude in infrared luminosity, L IR. Regarding the dust continuum, we use a mass-weighted dust temperature, T mw, determined using new empirical relations between temperature and luminosity. We find the average L/M mol gas mass conversion factors to be α850= 6.9×1012\, W\,Hz-1\,M-1, α CO = 4\,M (K\,km\,s-1\,pc2)-1 and α CI = 17.0 \,M (K\,km\,s-1\,pc2)-1, based on the assumption that the mean dust properties of the sample (H = gas-to-dust ratio/dust emissivity) will be similar to those of local metal rich galaxies and the MW. The tracer with the least intrinsic scatter is [CI](1-0), while CO(1-0) has the highest. The conversion factors show a weak but significant correlation with L IR. Assuming dust properties typical of metal-rich galaxies, we infer a neutral carbon abundance X CI = [C0/ mol]=1.6× 10-5, similar to that in the MW. We find no evidence for bimodality of α CO between main-sequence (MS) galaxies and those with extreme star-formation intensity, i.e. ULIRGs and SMGs. The means of the three conversion factors are found to be similar between MS galaxies and ULIRGs/SMGs, to within 10-20%. We show that for metal-rich galaxies, near-universal average values for α CO, X CI and H are adequate for global molecular gas estimates.