Cosmic-ray induced destruction of CO in star-forming galaxies

Abstract

We explore the effects of the expected higher cosmic ray (CR) ionization rates ζ CR on the abundances of carbon monoxide (CO), atomic carbon (C), and ionized carbon (C+) in the H2 clouds of star-forming galaxies. The study of Bisbas et al. (2015) is expanded by: a) using realistic inhomogeneous Giant Molecular Cloud (GMC) structures, b) a detailed chemical analysis behind the CR-induced destruction of CO, and c) exploring the thermal state of CR-irradiated molecular gas. CRs permeating the interstellar medium with ζ CR 10×(Galactic) are found to significantly reduce the [CO]/[H2] abundance ratios throughout the mass of a GMC. CO rotational line imaging will then show much clumpier structures than the actual ones. For ζ CR 100×(Galactic) this bias becomes severe, limiting the utility of CO lines for recovering structural and dynamical characteristics of H2-rich galaxies throughout the Universe, including many of the so-called Main Sequence (MS) galaxies where the bulk of cosmic star formation occurs. Both C+ and C abundances increase with rising ζ CR, with C remaining the most abundant of the two throughout H2 clouds, when ζ CR (1-100)×(Galactic). C+ starts to dominate for ζ CR 103×(Galactic). The thermal state of the gas in the inner and denser regions of GMCs is invariant with T gas 10\, K for ζ CR (1-10)×(Galactic). For ζ CR 103×(Galactic) this is no longer the case and T gas 30-50\, K are reached. Finally we identify OH as the key species whose T gas-sensitive abundance could mitigate the destruction of CO at high temperatures.