H2CO in the Horsehead PDR: Photo-desorption of dust grain ice mantles

TL;DR

This study investigates the role of grain surface chemistry in the Horsehead PDR, revealing that photo-desorption from dust grains significantly contributes to gas-phase H2CO, unlike in the dense core where gas-phase chemistry suffices.

Contribution

First observational evidence showing that photo-desorption from dust grains is essential for H2CO presence in the Horsehead PDR, contrasting with the dense core where gas-phase chemistry dominates.

Findings

H2CO abundance is similar in PDR and dense core (~2-3 x 10^-10).

Gas-phase chemistry explains H2CO in the dense core.

Photo-desorption is necessary to explain H2CO in the PDR.

Abstract

Aims: For the first time we investigate the role of the grain surface chemistry in the Horsehead Photo-dissociation region (PDR). Methods: We performed deep observations of several H2CO rotational lines toward the PDR and its associated dense-core in the Horsehead nebula, where the dust is cold ($\Td \simeq 20-30$ K). We complemented these observations with a map of the p-H2CO $~3_{03}-2_{02}$ line at 218.2 GHz (with 12" angular resolution). We determine the H2CO abundances using a detailed radiative transfer analysis and compare these results with PDR models that include either pure gas-phase chemistry or both gas-phase and grain surface chemistry. Results: The H2CO abundances ($\simeq 2-3 \times 10^{-10}$) with respect to H-nuclei are similar in the PDR and dense-core. In the dense-core the pure gas-phase chemistry model reproduces the observed H2CO abundance. Thus, surface processes do not contribute significantly to the gas-phase H2CO abundance in the core. In contrast, the formation of H2CO on the surface of dust grains and subsequent photo-desorption into the gas-phase are needed in the PDR to explain the observed gas-phase H2CO abundance, because the gas-phase chemistry alone does not produce enough H2CO. The assignments of different formation routes are strengthen by the different measured ortho-to-para ratio of H2CO: the dense-core displays the equilibrium value ($\sim3$) while the PDR displays an out-of-equilibrium value ($\sim2$). Conclusions: Photo-desorption of H2CO ices is an efficient mechanism to release a significant amount of gas-phase H2CO into the Horsehead PDR.