Tight correlation of star formation with [Ci] and CO lines across cosmic time

Abstract

Context. Cold molecular gas tracers, such as CI and CO lines, have been widely used to infer specific characteristics of the ISM and to derive star-formation relations among galaxies. Aims. However, there is still a lack of systematic studies of the star-formation scaling relation of CO and [CI] lines across cosmic time on multiple physical scales. Methods. We used observations of the ground state transitions of [CI], CO, and [CII], for 885 sources collected from the literature, to infer possible correlations between line luminosities of L'[CI](1-0), L'CO(1-0), and L'[CII] with star formation rates (SFR). With linear regression, we fit the relations between SFR and molecular mass derived from CO, CI, and CII lines. Results. The relation between [CI] and CO-based total molecular masses is weakly superlinear. Nevertheless, they can be calibrated against each other. For αCO = 0.8 and 4.0\ M\,(K\,km\,s-1\,pc2)-1 we derive α [CI] = 3.9 and 17\ M\,(K\,km\,s-1\,pc2)-1 , respectively. Using the lmfit package, we derived relation slopes of SFR-- L'[CI](1-0), SFR-- L'CO(1-0), and SFR-- L'[CII](1-0) to be β = 1.06 0.02, 1.24 0.02, and 0.74 0.02, respectively. With a Bayesian-inference linmix method, we find consistent results. Conclusions. Our relations for [CI](1-0) and CO(1-0) indicate that they trace similar molecular gas contents, across different redshifts and different types of galaxies. This suggests that these correlations do not have strong evolution with cosmic time.