Turbulent dissipation, CH+ abundance, H2 line luminosities, and polarization in the cold neutral medium

Abstract

In the cold neutral medium, high out-of-equilibrium temperatures are created by intermittent dissipation processes, including shocks, viscous heating, and ambipolar diffusion. The high-temperature excursions are thought to explain the enhanced abundance of CH+ observed along diffuse molecular sight-lines. Intermittent high temperatures should also have an impact on H2 line luminosities. We carry out simulations of MHD turbulence in molecular clouds including heating and cooling, and post-process them to study H2 line emission and hot-gas chemistry, particularly the formation of CH+. We explore multiple magnetic field strengths and equations of state. We use a new H2 cooling function for n H ≤ 105\, cm-3, T≤ 5000\, K, and variable H2 fraction. We make two important simplifying assumptions: (i) the H2/ H fraction is fixed everywhere, and (ii) we exclude from our analysis regions where the ion-neutral drift velocity is calculated to be greater than 5 km/s. Our models produce H2 emission lines in accord with many observations, although extra excitation mechanisms are required in some clouds. For realistic r.m.s. magnetic field strengths (≈ 10 μG) and velocity dispersions, we reproduce observed CH+ abundances. These findings contrast with those of Valdivia et al. (2017). Comparison of predicted dust polarization with observations by Planck suggests that the mean field 5 μG, so that the turbulence is sub-Alfv\'enic. We recommend future work treating ions and neutrals as separate fluids to more accurately capture the effects of ambipolar diffusion on CH+ abundance.