[CII] 158 μ m emission as an indicator of galaxy star formation rate

Abstract

Observations of local star-forming galaxies (SFGs) show a tight correlation between their singly ionized carbon line luminosity (L [CII]) and star formation rate (SFR), suggesting that L [CII] may be a useful SFR tracer for galaxies. Some other galaxy populations, however, are found to have lower L [CII]/ SFR than the local SFGs, including the infrared-luminous, starburst galaxies at low and high redshifts, as well as some moderately star-forming galaxies at the epoch of re-ionization (EoR). The origin of this ` [CII] deficit' is unclear. In this work, we study the L [CII]-SFR relation of galaxies using a sample of z=0-8 galaxies with M*≈107-5×1011\,M extracted from cosmological volume and zoom-in simulations from the Feedback in Realistic Environments (FIRE) project. We find a simple analytic expression for L [CII]/SFR of galaxies in terms of the following parameters: mass fraction of [CII]-emitting gas (f [CII]), gas metallicity (Z gas), gas density (n gas) and gas depletion time (t dep=M gas/ SFR). We find two distinct physical regimes, where t dep (Z gas) is the main driver of the [CII] deficit in H2-rich ( H2-poor) galaxies. The observed [CII] deficit of IR-luminous galaxies and early EoR galaxies, corresponding to the two different regimes, is due to short gas depletion time and low gas metallicity, respectively. Our result indicates that [CII] deficit is a common phenomenon of galaxies, and caution needs to be taken when applying a constant L [CII]-to-SFR conversion factor derived from local SFGs to estimate cosmic SFR density at high redshifts and interpret data from upcoming [CII] line intensity mapping experiments.