Infrared resonant vibrationally induced restructuring of amorphous solid water

TL;DR

This study demonstrates that targeted infrared irradiation of amorphous solid water induces structural reorganization towards a more crystalline state, with implications for understanding interstellar ice chemistry.

Contribution

First experimental evidence showing IR vibrational mode pumping causes restructuring of hydrogen bonds in amorphous ice, supported by molecular dynamics simulations.

Findings

IR irradiation modifies IR absorption bands indicating increased crystallinity

Up to 94% of irradiated ice undergoes structural change

Restructuring saturates within minutes of irradiation

Abstract

Amorphous solid water (ASW) is abundantly present in the interstellar medium, where it forms a mantle on interstellar dust particles and it is the precursor for cometary ices. In space, ASW acts as substrate for interstellar surface chemistry leading to complex molecules and it is postulated to play a critical role in proton-transfer reactions. Although ASW is widely studied and is generally well characterized by different techniques, energetically-induced structural changes, such as ion, electron and photon irradiation, in these materials are less well understood. Selective pumping of specific infrared (IR) vibrational modes can aid in understanding the role of vibrations in restructuring of hydrogen bonding networks. Here we present the first experimental results on hydrogen bonding changes in ASW induced by the intense, nearly monochromatic mid-IR free-electron laser (FEL) radiation of the FELIX-2 beamline at the FELIX Laboratory at the Radboud University in Nijmegen, the Netherlands. The changes are monitored by reflection-absorption infrared spectroscopy. Upon resonant irradiation, a modification in IR absorption band profile of ASW is observed in agreement with a growing crystalline-like contribution and a decreasing amorphous contribution. This phenomenon saturates within a few minutes of FEL irradiation, modifying upwards of 94~\% of the irradiated ice. The effect is further analysed in terms of hydrogen bonding donors and acceptors and the experiments are complimented with Molecular Dynamics simulations to constrain the effect at the molecular level.