Modeling of diffuse molecular gas applied to HD 102065 observations

TL;DR

This study models a diffuse molecular cloud toward HD 102065, comparing predictions with observations to understand physical conditions and chemistry, highlighting the role of warm, turbulent gas in molecular excitation.

Contribution

It introduces a detailed modeling approach that explains molecular excitation in diffuse clouds by incorporating warm, turbulent gas, challenging previous assumptions about uniform conditions.

Findings

Consistent cloud model with Galactic radiation field, density 80 cm-3, temperature 60-80 K.

Warm, dense gas within 0.03 pc explains excited H2 and CH+ observations.

Turbulent dissipation heats molecular gas, influencing chemical abundances.

Abstract

Aims. We model a diffuse molecular cloud present along the line of sight to the star HD 102065. We compare our modeling with observations to test our understanding of physical conditions and chemistry in diffuse molecular clouds. Methods. We analyze an extensive set of spectroscopic observations which characterize the diffuse molecular cloud observed toward HD 102065. Absorption observations provide the extinction curve, H2, C I, CO, CH, and CH+ column densities and excitation. These data are complemented by observations of CII, CO and dust emission. Physical conditions are determined using the Meudon PDR model of UV illuminated gas. Results. We find that all observational results, except column densities of CH, CH+ and H2 in its excited (J > 2) levels, are consistent with a cloud model implying a Galactic radiation field (G~0.4 in Draine's unit), a density of 80 cm-3 and a temperature (60-80 K) set by the equilibrium between heating and cooling processes. To account for excited (J >2) H2 levels column densities, an additional component of warm (~ 250K) and dense (nH>10^4 cm-3) gas within 0.03 pc of the star would be required. This solution reproduces the observations only if the ortho-to-para H2 ratio at formation is 1. In view of the extreme physical conditions and the unsupported requirement on the ortho-to-para ratio, we conclude that H2 excitation is most likely to be accounted for by the presence of warm molecular gas within the diffuse cloud heated by the local dissipation of turbulent kinetic energy. This warm H2 is required to account for the CH+ column density. It could also contribute to the CH abundance and explain the inhomogeneity of the CO abundance indicated by the comparison of absorption and emission spectra.