English

The X_CO conversion factor from galactic multiphase ISM simulations

Astrophysics of Galaxies 2018-05-16 v1

Abstract

CO(J=1-0) line emission is a widely used observational tracer of molecular gas, rendering essential the X_CO factor, which is applied to convert CO luminosity to H_2 mass. We use numerical simulations to study how X_CO depends on numerical resolution, non-steady-state chemistry, physical environment, and observational beam size. Our study employs 3D magnetohydrodynamics (MHD) simulations of galactic disks with solar neighborhood conditions, where star formation and the three-phase interstellar medium (ISM) are self-consistently regulated by gravity and stellar feedback. Synthetic CO maps are obtained by post-processing the MHD simulations with chemistry and radiation transfer. We find that CO is only an approximate tracer of H_2. On parsec scales, W_CO is more fundamentally a measure of mass-weighted volume density, rather than H_2 column density. Nevertheless, XCO=0.71.0×1020 cm2K1km1s\langle X_\mathrm{CO} \rangle=0.7-1.0\times10^{20}~\mathrm{cm^{-2}K^{-1}km^{-1}s} consistent with observations, insensitive to the evolutionary ISM state or radiation field strength if steady-state chemistry is assumed. Due to non-steady-state chemistry, younger molecular clouds have slightly lower X_CO and flatter profiles of X_CO versus extinction than older ones. The CO-dark H_2 fraction is 26-79 %, anti-correlated with the average extinction. As the observational beam size increases from 1 pc to 100 pc, X_CO increases by a factor of ~ 2. Under solar neighborhood conditions, X_CO in molecular clouds is converged at a numerical resolution of 2 pc. However, the total CO abundance and luminosity are not converged even at the numerical resolution of 1 pc. Our simulations successfully reproduce the observed variations of X_CO on parsec scales, as well as the dependence of X_CO on extinction and the CO excitation temperature.

Keywords

Cite

@article{arxiv.1803.09822,
  title  = {The X_CO conversion factor from galactic multiphase ISM simulations},
  author = {Munan Gong and Eve C. Ostriker and Chang-Goo Kim},
  journal= {arXiv preprint arXiv:1803.09822},
  year   = {2018}
}

Comments

accepted by ApJ

R2 v1 2026-06-23T01:05:45.558Z