Production of H+3 via photodissociation of organic molecules in interstellar clouds

We present experimental results obtained from photoionization and photodissociation processes of abundant interstellar CH3-X type organic molecules like methanol (CH3OH), methylamine (CH3NH2) and acetonitrile (CH3CN) as alternative route for the production of H+3 in interstellar and star forming environments. The measurements were taken at the Brazilian Synchrotron Light Laboratory (LNLS), employing soft X-ray photons with energies between 200 and 310 eV and time of flight mass spectrometry. Mass spectra were obtained using the photoelectron-photoion coincidence techniques. Absolute averaged cross sections for H+3 production by soft X-rays were determined. We have found that, among the channels leading to molecular dissociation, the H+3 yield could reach values up to 0.7% for single photoionization process and up to 4% for process involving double photoionization. The H+3 photoproduction cross section due to the dissociation of the studied organic molecules by photons over the C1s edge (200-310 eV) were about 0.2-1.4 × 10−18 cm2. Adopting the typical X-ray luminosity LX & 1031 erg s−1 which best fit the observational data for AFGL 2591 (Stäuber et al. 2005) we derive an estimative for the H+3 photoproduction rate due to methyl-compounds dissociation process. The highest value for the H+3 column density from methanol dissociation by soft X-rays, assuming a steady state scenario, was about 1011 cm2, which gives the fraction of the photoproduced H+3 of about 0.05%, as in the case of dense molecular cloud AFGL 2591. Despite the extreme small value, this represent a new and alternative source of H+3 into dense molecular clouds and it is not been considered as yet in interstellar chemistry models.