Dynamical Effects of the Radiative Stellar Feedback on the H I-to-H2 transition [GA]

http://arxiv.org/abs/2109.05886


The atomic-to-molecular hydrogen (H/H2) transition has been extensively studied as it controls the fraction of gas in molecular state in an interstellar cloud. This fraction is linked to star-formation by the Schmidt-Kennicutt law. While theoretical estimates (Sternberg et al. 2014) of the column density of the H I layer have been proposed for static photodissociation regions (PDRs), Herschel and well-resolved ALMA observations have revealed dynamical effects in star forming regions, caused by the process of photo-evaporation. We extend the analytic study of the H/H2 transition to include the effects of the propagation of the ionization front, in particular in presence of photo-evaporation at the walls of blister H II regions, and find its consequences on the total atomic hydrogen column density at the surface of clouds in presence of a UV field, and on the properties of the H/H2 transition. We solve semi-analytically the differential equation giving the H2 column density profile taking into account H2 formation on grains, H2 photodissociation and the ionization front propagation dynamics modeled as an advection of the gas through the ionization front. Taking into account this advection reduces the width of the atomic region compared to static models. The atomic region may disappear if the ionization front velocity exceeds a certain value, leading the H/H2 transition and the ionization front to merge. For both dissociated and merged configurations, we provide analytical expressions to determine the total H I column density. Our results take into account the metallicity. Finally, we compared our results to observations of PDRs illuminated by O-stars, for which we concluded that the dynamical effects are strong, especially for low-excitation PDRs.

Read this paper on arXiv…

V. Maillard, E. Bron and F. Petit
Tue, 14 Sep 21
68/88

Comments: Accepted by Astronomy & Astrophysics on September, 11th 2021. 18 pages, 16 figures