2017A&A...601A..78R

Aims. We aim to explore the capabilities of dust emission and γ rays for probing the properties of the interstellar medium in the nearby anti-centre region, using γ-ray observations with the Fermi Large Area Telescope (LAT), and the thermal dust optical depth inferred from Planck andIRAS observations. We also aim to study massive star-forming clouds including the well known Taurus, Auriga, Perseus, and California molecular clouds, as well as a more diffuse structure which we refer to as Cetus.In particular, we aim at quantifying potential variations in cosmic-ray density and dust properties per gas nucleon across the different gas phases and different clouds, and at measuring the CO-to-H₂ conversion factor, X_CO, in different environments.
Methods. We have separated six nearby anti-centre clouds that are coherent in velocities and distances, from the Galactic-disc background in HI 21-cm and ¹²CO 2.6-mm line emission. We have jointly modelled the γ-ray intensity recorded between 0.4 and 100GeV, and the dust optical depth τ₃₅₃ at 353 GHz as a combination of HI-bright, CO-bright, and ionised gas components. The complementary information from dust emission and γ rays was used to reveal the gas not seen, or poorly traced, by HI, free-free, and ¹²CO emissions, namely (i) the opaque HIAND DIFFUSE H₂ present in the Dark Neutral Medium at the atomic-molecular transition, and (ii) the dense H₂ to be added where ¹²CO lines saturate.
Results. The measured interstellar γ-ray spectra support a uniform penetration of the cosmic rays with energies above a few GeV through the clouds, from the atomic envelopes to the ¹²CO-bright cores, and with a small±9% cloud-to-cloud dispersion in particle flux. We detect the ionised gas from the HIIREGION NGC 1499IN THE DUST AND γ-ray emissions and measure its mean electron density and temperature. We find a gradual increase in grain opacity as the gas (atomic or molecular) becomes more dense. The increase reaches a factor of four to six in the cold molecular regions that are well shielded from stellar radiation. Consequently, the X_CO factor derived from dust is systematically larger by 30% to 130% than the γ-ray estimate. We also evaluate the average γ-ray X_CO factor for each cloud, and find that X_CO tends to decrease from diffuse to more compact molecular clouds, as expected from theory. We find X_CO factors in the anti-centre clouds close to or below 10²⁰cm^–2K^–1/(km/s), in agreement with other estimates in the solar neighbourhood. Together, they confirm the long-standing unexplained discrepancy, by a factor of two, between the mean X_CO values measured at parsec scales in nearby clouds and those obtained at kiloparsec scale in the Galaxy. Our results also highlight large quantitative discrepancies in ¹²CO intensities between simulations and observations at low molecular gas densities.