Cosmic evolution of the [CII]-to-molecular gas relation

Abstract

The [CII] 158 μm line is widely used to trace star formation and the gas contents of high-redshift galaxies. However, it remains unclear under which physical conditions it reliably traces the molecular reservoir, and whether a unique conversion factor α [CII] can be applied across cosmic time. We investigate the evolution of the relation between the [CII] luminosity and molecular gas mass from z10 to z0.2 using the Vintergatan simulation, a high-resolution cosmological zoom-in of a Milky Way-like galaxy. We post-process the snapshots with the Skirt radiative transfer code to generate synthetic [CII] data cubes. We measure global and spatially resolved (100 pc) relations between [CII] luminosity (L [CII]), star formation rate (SFR), and molecular gas mass (M mol). We follow the redshift evolution of the [CII]-to-molecular gas conversion factor α [CII], and link these trends to the evolution of the interstellar medium (ISM) phases. The global L [CII]-M mol and L [CII]-SFR relations evolve from a steep, [CII]-deficient regime at very low metallicity to an almost linear behaviour, similar to calibrations at z≈2, once the ISM reaches Z 0.05-0.1\,Z at z5. Over this evolution, α [CII] spans nearly three orders of magnitude, from 104 down to ≈10 \,M\,L-1, even though the [CII] emission remains spatially correlated with the molecular gas. A unique, redshift-independent α [CII] therefore cannot recover molecular gas masses across the regimes we explore. [CII] remains a viable tracer of molecular gas at very high redshifts, but only when used with conversion factors that explicitly account for metallicity, ISM phase mix, and merger events.