SIMBAD references

The [CII] 158µm line is an important tool for understanding the life cycle of interstellar matter. Ionized carbon is present in a variety of phases of the interstellar medium (ISM), including the diffuse ionized medium, warm and cold atomic clouds, clouds in transition from atomic to molecular, and dense and warm photon dominated regions. Velocity-resolved observations of [CII] are the most powerful technique available to disentangle the emission produced by these components. These observations can also be used to trace CO-dark H₂ gas and determine the total mass of the ISM. The Galactic Observations of Terahertz C+ (GOTC+) project surveys the [CII] 158µm line over the entire Galactic disk with velocity-resolved observations using the Herschel/HIFI instrument. We present the first longitude-velocity maps of the [CII] emission for Galactic latitudes b=0°, ±0.5°, and ±1.0°. We combine these maps with those of HI, ¹²CO, and ¹³CO to separate the different phases of the ISM and study their properties and distribution in the Galactic plane. [CII] emission is mostly associated with spiral arms, mainly emerging from Galactocentric distances between 4 and 10kpc. It traces the envelopes of evolved clouds as well as clouds that are in the transition between atomic and molecular. We estimate that most of the observed [CII] emission is produced by dense photon dominated regions (∼47%), with smaller contributions from CO-dark H₂ gas (∼28%), cold atomic gas (∼21%), and ionized gas (∼4%). Atomic gas inside the Solar radius is mostly in the form of cold neutral medium (CNM), while the warm neutral medium gas dominates the outer galaxy. The average fraction of CNM relative to total atomic gas is ∼43%. We find that the warm and diffuse CO-dark H₂ is distributed over a larger range of Galactocentric distances (4-11kpc) than the cold and dense H₂ gas traced by ¹²CO and ¹³CO (4-8kpc). The fraction of CO-dark H₂ to total H₂ increases with Galactocentric distance, ranging from ∼20% at 4kpc to ∼80% at 10kpc. On average, CO-dark H₂ accounts for ∼30% of the molecular mass of the Milky Way. When the CO-dark H₂ component is included, the radial distribution of the CO-to-H₂ conversion factor is steeper than that when only molecular gas traced by CO is considered. Most of the observed [CII] emission emerging from dense photon dominated regions is associated with modest far-ultraviolet fields in the range χ₀≃1-30.