Changes in the morphology of interstellar ice analogues after hydrogen atom exposure

TL;DR

This study investigates how hydrogen atom exposure alters the morphology of interstellar ice analogues, showing that hydrogen exposure reduces porosity and compacts the ice, which supports the idea that interstellar ice is amorphous and non-porous.

Contribution

It provides experimental evidence that hydrogen atom exposure causes exponential porosity decrease in amorphous ice, linking energy transfer to ice compaction in interstellar conditions.

Findings

Porosity decreases exponentially with hydrogen exposure.

Porosity reduction is proportional to ice thickness.

Energy transfer from hydrogen recombination causes ice compaction.

Abstract

The morphology of water ice in the interstellar medium is still an open question. Although accretion of gaseous water could not be the only possible origin of the observed icy mantles covering dust grains in cold molecular clouds, it is well known that water accreted from the gas phase on surfaces kept at 10 K forms ice films that exhibit a very high porosity. It is also known that in the dark clouds H2 formation occurs on the icy surface of dust grains and that part of the energy (4.48 eV) released when adsorbed atoms react to form H2 is deposited in the ice. The experimental study described in the present work focuses on how relevant changes of the ice morphology result from atomic hydrogen exposure and subsequent recombination. Using the temperature-programmed desorption (TPD) technique and a method of inversion analysis of TPD spectra, we show that there is an exponential decrease in the porosity of the amorphous water ice sample following D-atom irradiation. This decrease is inversely proportional to the thickness of the ice and has a value of Phi_0 = 2 x 10^16 D-atoms/cm^2 per layer of H2O. We also use a model which confirms that the binding sites on the porous ice are destroyed regardless of their energy depth, and that the reduction of the porosity corresponds in fact to a reduction of the effective area. This reduction appears to be compatible with the fraction of D2 formation energy transferred to the porous ice network. Under interstellar conditions, this effect is likely to be efficient and, together with other compaction processes, provides a good argument to believe that interstellar ice is amorphous and non-porous.