Cool dark gas in Cygnus X: The first large-scale mapping of low-frequency carbon recombination lines

Abstract

Understanding the transition from atomic gas to molecular gas is critical to explain the formation and evolution of molecular clouds. However, the gas phases involved, cold HI and CO-dark molecular gas, are challenging to directly observe and physically characterize. We observed the Cygnus X star-forming complex in carbon radio recombination lines (CRRLs) at 274--399 MHz with the Green Bank Telescope at 48' (21 pc) resolution. Of the 30 deg2 surveyed, we detect line-synthesized C273α emission from 24 deg2 and produce the first large-area maps of low-frequency CRRLs, which likely originate in CO-dark molecular gas. The morphology of the C273α emission reveals arcs, ridges, and extended possibly sheet-like gas which are often on the outskirts of CO emission. We find a correlation between velocity-integrated C273α and the 8 μm intensity with a power-law slope of 1.3 0.2. We interpret the relation as the dependence of cool dark gas emission on the FUV radiation field, G0 ≈ 40 - 160. We determine the typical angular separation between C273α and 13CO emission to be 12 pc. Velocity differences between C273α and 13CO are apparent throughout the region and have a typical value of 2.9 km s-1. We estimate gas densities of n ≈ 20 - 900 cm-3 with a nominal n ≈ 400 cm-3 in the C+/H2 layer. The evolution of the C273α gas seems to be dominated by turbulent pressure, with a characteristic timescale to form H2 of about 2.6 Myr. These observations underline the richness of low-frequency CRRLs to provide revelatory insights into the characteristics of (CO-)dark gas and the evolution of molecular gas.