Reproducing the CO-to-H\(_2\) conversion factor in cosmological simulations of Milky Way-mass galaxies

We present models of CO(1-0) emission from Milky Way-mass galaxies at redshift zero in the FIRE-2 cosmological zoom-in simulations. We calculate the molecular abundances by post-processing the simulations with an equilibrium chemistry solver while accounting for the effects of local sources, and determine the emergent CO(1-0) emission using a line radiative transfer code. We find that the results depend strongly on the shielding length assumed, which in our models sets the attenuation of the incident UV radiation field. Commonly used choices for the shielding length, such as the Jeans length, result in CO abundances that are too high at a given H\(_2\) abundance. We find that a model with a distribution of shielding lengths, which has a median shielding length of \(\sim 3\) pc in cold gas (\(T < 300\) K) for both CO and H\(_{2}\), is able to reproduce both the observed CO(1-0) luminosity and inferred CO-to-H\(_{2}\) conversion factor at a given star formation rate compared with observations. We suggest that this short shielding length can be thought of as a subgrid model which controls the amount of radiation that penetrates giant molecular clouds.