C2H observations toward the Orion Bar

Abstract

C2H is one of the first radicals to be detected in the interstellar medium. Its higher rotational transitions have recently become available with the Herschel Space Observatory. We aim to constrain the physical parameters of the C2H emitting gas toward the Orion Bar. We analyse the C2H line intensities measured toward the Orion Bar CO+ Peak and Herschel/HIFI maps of C2H, CH, and HCO+, and a NANTEN map of [CI]. We interpret the observed C2H emission using radiative transfer and PDR models. Five rotational transitions of C2H have been detected in the HIFI frequency range toward the CO+ peak. A single component rotational diagram gives a rotation temperature of ~64 K and a beam-averaged C2H column density of 4×1013 cm-2. The measured transitions cannot be explained by any single parameter model. According to a non-LTE model, most of the C2H column density produces the lower-N C2H transitions and traces a warm (Tkin ~ 100-150 K) and dense (n(H2)~105-106 cm-3) gas. A small fraction of the C2H column density is required to reproduce the intensity of the highest-N transitions (N=9-8 and N=10-9) originating from a high density (n(H2)~5×106 cm-3) hot (Tkin ~ 400 K) gas. The total beam-averaged C2H column density in the model is 1014 cm-2. Both the non-LTE radiative transfer model and a simple PDR model representing the Orion Bar with a plane-parallel slab of gas and dust suggest, that C2H cannot be described by a single pressure component, unlike the reactive ion CH+, which was previously analysed toward the Orion Bar CO+ peak. The physical parameters traced by the higher rotational transitions (N=6-5,...,10-9) of C2H may be consistent with the edges of dense clumps exposed to UV radiation near the ionization front of the Orion Bar.