# Vacuum ultraviolet photodesorption and photofragmentation of   formaldehyde-containing ices

**Authors:** G\'eraldine F\'eraud, Mathieu Bertin, Claire Romanzin, R\'emi Dupuy,, Franck Le Petit, Evelyne Roueff, Laurent Philippe, Xavier Michaut, Pascal, Jeseck, Jean-Hugues Fillion

arXiv: 1905.08223 · 2019-05-21

## TL;DR

This study provides the first absolute measurements of vacuum ultraviolet photodesorption yields from formaldehyde ices, revealing mechanisms and efficiencies crucial for understanding molecular abundances in astrophysical environments.

## Contribution

It experimentally quantifies photodesorption yields of H$_2$CO from various ices and discusses the mechanisms involved, improving astrochemical models.

## Key findings

- H$_2$CO photodesorbs with an efficiency of ~4-10 x 10^{-4} molecules per photon.
- Photodesorption involves mechanisms like DIET, indirect DIET, and photochemical desorption.
- Yields and mechanisms can be integrated into astrochemical simulations.

## Abstract

Non-thermal desorption from icy grains containing H$_2$CO has been invoked to explain the observed H$_2$CO gas phase abundances in ProtoPlanetary Disks (PPDs) and Photon Dominated Regions (PDRs). Photodesorption is thought to play a key role, however no absolute measurement of the photodesorption from H$_2$CO ices were performed up to now, so that a default value is used in the current astrophysical models. As photodesorption yields differ from one molecule to the other, it is crucial to experimentally investigate photodesorption from H$_2$CO ices.   We measured absolute wavelength-resolved photodesorption yields from pure H$_2$CO ices, H$_2$CO on top of a CO ice (H$_2$CO/CO), and H$_2$CO mixed with CO ice (H$_2$CO:CO) irradiated in the Vacuum UltraViolet (VUV) range (7-13.6~eV). Photodesorption from a pure H$_2$CO ice releases H$_2$CO in the gas phase, but also fragments, such as CO and H$_2$. Energy-resolved photodesorption spectra, coupled with InfraRed (IR) and Temperature Programmed Desorption (TPD) diagnostics, showed the important role played by photodissociation and allowed to discuss photodesorption mechanisms. For the release of H$_2$CO in the gas phase, they include Desorption Induced by Electronic Transitions (DIET), indirect DIET through CO-induced desorption of H$_2$CO and photochemical desorption.   We found that H$_2$CO photodesorbs with an average efficiency of $\sim 4-10 \times 10^{-4}$ molecule/photon, in various astrophysical environments. H$_2$CO and CO photodesorption yields and photodesorption mechanisms, involving photofragmentation of H$_2$CO, can be implemented in astrochemical codes. The effects of photodesorption on gas/solid abundances of H$_2$CO and all linked species from CO to Complex Organic Molecules (COMs), and on the H$_2$CO snowline location, are now on the verge of being unravelled.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1905.08223/full.md

## References

129 references — full list in the complete paper: https://tomesphere.com/paper/1905.08223/full.md

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Source: https://tomesphere.com/paper/1905.08223