The cosmic ray ionization rate in the Galactic disk, as determined from observations of molecular ions

Abstract

We have obtained estimates for the cosmic-ray ionization rate (CRIR) in the Galactic disk, using a detailed model for the physics and chemistry of diffuse interstellar gas clouds to interpret previously-published measurements of the abundance of four molecular ions: ArH+, OH+, H2O+ and H3+. For diffuse atomic clouds at Galactocentric distances in the range Rg 4 - 9 kpc, observations of ArH+, OH+, and H2O+ imply a mean primary CRIR of (2.2 0.3) [(R0-Rg)/4.7\,kpc] × 10-16 \, s-1 per hydrogen atom, where R0=8.5 kpc. Within diffuse molecular clouds observed toward stars in the solar neighborhood, measurements of H3+ and H2 imply a primary CRIR of (2.3 0.6) × 10-16\,\, s-1 per H atom, corresponding to a total ionization rate per H2 molecule of (5.3 1.1) × 10-16\,\, s-1, in good accord with previous estimates. These estimates are also in good agreement with a rederivation, presented here, of the CRIR implied by recent observations of carbon and hydrogen radio recombination lines along the sight-line to Cas A. Here, our best-fit estimate for the primary CRIR is 2.9 × 10-16\,\, s-1 per H atom. Our results show marginal evidence that the CRIR in diffuse molecular clouds decreases with cloud extinction, A V( tot), with a best-fit dependence A V( tot)-1 for A V( tot) 0.5.