CO-dark molecular gas traced by HCO+ in the diffuse interstellar medium

Abstract

A classic problem in the study of the interstellar medium (ISM) is the near-invisibility of molecular hydrogen (H2) in cold environments. Observations of CO emission are typically used to indirectly trace H2, but a significant fraction of H2 in the diffuse ISM is not associated with any detectable CO emission (``CO-dark'' molecular gas). Meanwhile, observations of H2 absorption trace nearly all of the H2 in diffuse directions. In particular, a kinematically broad HCO+ absorption signature traces extremely diffuse, CO-dark H2. We have used sensitive observations of HCO+, CO, and atomic hydrogen (HI) in absorption to constrain the properties of such diffuse molecular gas in five directions. The diffuse molecular gas revealed by broad HCO+ absorption has a lower fraction of cold HI (fCNM = 0.38+0.28-0.27) and a lower fraction of hydrogen in H2 (fmol=0.09+0.06-0.03) than gas traced by CO in the same directions. We detect almost no CO absorption from the gas traced by broad HCO+ absorption. We constrain the CO abundance relative to H2 to be 10-6-10-5 for gas traced by both broad and narrow HCO+ absorption, consistent with chemical model predictions for the diffuse ISM. We further show that neither CO emission nor absorption is likely to be detected where N(H2)×1019 cm-2 - a result of both the low CO abundance and the low H2 column - while HCO+ absorption is readily detected for N(H2)×1018 cm-2. These results demonstrate that even modest amounts of cold HI can bear H2, providing critical constraints on the HI-to-H2 transition in the ISM.