Reaction Studies of Neutral Atomic C with H3+ using a Merged-Beams Apparatus

Abstract

We have investigated the chemistry of C + H3+ forming CH+, CH2+, and CH3+. These reactions are believed to be some of the key gas-phase astrochemical processes initiating the formation of organic molecules in molecular clouds. For this work we have constructed a novel merged fast-beams apparatus which overlaps a beam of molecular ions onto a beam of ground-term neutral atoms. Here we present cross section data for forming CH+ and CH2+ at collision energies from ≈ 9 meV to ≈20 and 3 eV, respectively. Using these data we have derived thermal rate coefficients for reaction temperatures from ≈72 K to ≈2.3 × 105 and 3.4 × 104 K, respectively. For the formation of CH3+ we are able only to put an upper limit on the rate coefficient. Our results for CH+ and CH2+ are in good agreement with the mass-scaled results from a previous ion trap study of C + D3+ at a reaction temperature of 1000 K. At molecular cloud temperatures our thermal rate coefficient for forming CH+ lies a factor of 2-4 below the Langevin rate coefficient currently given in astrochemical databases and below the published semi-classical calculations. Our results for CH2+ formation are a factor of 26 above the semi-classical results. Astrochemical databases do not currently include this channel.