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Understanding the molecular gas content in the interstellar medium (ISM) is crucial for studying star formation and galaxy evolution. The CO-to-H 2 ( X CO ) and the C I -to-H 2 ( X CI ) conversion factors are widely used to estimate the molecular mass content in galaxies. However, these factors depend on many environmental parameters in the ISM, such as metallicity, cosmic-ray ionization rate, and far-ultraviolet (FUV) radiation field, in particular, in the low-metallicity ISM that is found at large galactocentric radii and in early-type galaxies. This work investigates the dependence of X CO and X CI on the environmental parameters of the ISM, with a focus on the low-metallicity α -enhanced ISM (C/O < 0), to provide improved tracers of molecular gas under diverse conditions. We used the statistical algorithm PDFCHEM, coupled with a database of photodissociation region (PDR) models generated with the 3D-PDR astrochemical code. The models account for a wide range of metallicities, dust-to-gas mass ratios, FUV intensities, and cosmic-ray ionization rates. The conversion factors were computed by integrating the PDR properties over log-normal column density distributions ( A V -PDFs) that represent various cloud types. The X CO factor increases significantly with decreasing metallicity. It exceeds ∼1000 times the Galactic value at O/H = −1.0 under α -enhanced conditions, as opposed to ∼300 times under non- α -enhanced conditions (C/O = 0). In contrast, X CI varies more gradually with metallicity, which makes it a more reliable tracer of molecular gas in metal-poor environments under most conditions. The fraction of CO-dark molecular gas increases dramatically in low-metallicity regions, where it exceeds 90% at O/H = −1.0, in particular, in diffuse clouds and environments with strong FUV radiation fields. The results highlight the limitations of CO as a molecular gas tracer in the metal-poor ISM and demonstrate the potential of C I (1–0) as a complementary tracer. The use of metallicity-dependent X CO and X CI factors as provided by this study is recommended for accurately estimating molecular gas masses in diverse environments. We recommend the use of the log 10 X CO ≃ −2.41 Z + 41.3 relation for the CO-to-H 2 conversion factor and the log 10 X CI ≃ −0.99 Z + 29.7 relation for the C I -to-H 2 conversion factor, where Z = 12 + log 10 (O/H).
Bisbas et al. (Fri,) studied this question.