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Molecular Fingerprints of Ice Surfaces in Sum Frequency Generation Spectra: A First-Principles Machine Learning Study

Margaret L. Berrens, Marcos F. Calegari Andrade, John T. Fourkas, Tuan Anh Pham, Davide Donadio

2025JACS Au10 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Understanding the molecular-level structure and dynamics of ice surfaces is crucial for deciphering several chemical, physical, and atmospheric processes. Vibrational sum-frequency generation (SFG) spectroscopy is the most prominent tool for probing the molecular-level structure of the air–ice interface as it is a surface-specific technique, but the molecular interpretation of SFG spectra is challenging. This study utilizes a machine-learning potential, along with dipole and polarizability models trained on ab initio data, to calculate the SFG spectrum of the air–ice interface. At temperatures below ice surface premelting, our simulations support the presence of a proton-ordered arrangement at the Ice I h surface, similar to that seen in Ice XI. Additionally, our simulations provide insight into the assignment of SFG peaks to specific molecular configurations where possible and assess the contribution of subsurface layers to the overall SFG spectrum. These insights enhance our understanding and interpretation of vibrational studies of environmental chemistry at the ice surface.

Topics & Concepts

PolarizabilitySum-frequency generationChemistryDipoleSum frequency generation spectroscopyPremeltingMolecular dynamicsChemical physicsSpectral lineIce IhSpectroscopyAb initioInfrared spectroscopyComputational chemistryMoleculeMolecular physicsPhysicsOpticsNonlinear opticsLaserOrganic chemistryAstronomyMelting pointQuantum mechanicsSpectroscopy and Quantum Chemical StudiesSpectroscopy and Laser ApplicationsAtmospheric Ozone and Climate
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