JWST reveals cosmic ray dominated chemistry in the local ULIRG IRAS 07251-0248

Abstract

We analyse the ro-vibrational absorption bands of various molecular cations (HCO+, HCNH+, and N2H+) and neutral species (HCN, HNC, and HC3N) detected in the James Webb Space Telescope/Mid-Infrared Instrument Medium Resolution Spectrometer spectrum (4.9--27.9\,) of the local ultra luminous infrared galaxy IRAS~07251-0248. We find that the molecular absorptions are blueshifted by 160\,km\,s-1 relative to the systemic velocity of the target. Using local thermal equilibrium (LTE) excitation models, we derive rotational temperatures (T rot) from 42 to 185\,K for these absorption bands. This range of measured T rot can be explained by infrared (IR) radiative pumping as a by--product of the strength, effective critical density, and opacity of each molecular band. Thus, these results suggest that these absorptions originate in a warm expanding gas shell (M90--330\,M\,yr-1), which might be the base of the larger scale cold molecular outflow detected in this source. Finally, the elevated abundance of molecular cations can be explained by a high cosmic ray ionization rate, with log(ζH2/n H\, [cm3\, s-1]) in the range of -18.2 (from H3+) to -19.1 (inferred from HCO+ and N2H+, which are likely tracing denser gas), consistent with a cosmic ray dominated chemistry as predicted by chemical models.