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Quasi-one-dimensional hydrogen bonding in nanoconfined ice

Pavan Ravindra, Xavier R. Advincula, Christoph Schran, Angelos Michaelides, Venkat Kapil

2024Nature Communications24 citationsDOIOpen Access PDF

Abstract

The Bernal-Fowler ice rules stipulate that each water molecule in an ice crystal should form four hydrogen bonds. However, in extreme or constrained conditions, the arrangement of water molecules deviates from conventional ice rules, resulting in properties significantly different from bulk water. In this study, we employ machine learning-driven first-principles simulations to identify a new stabilization mechanism in nanoconfined ice phases. Instead of forming four hydrogen bonds, nanoconfined crystalline ice can form a quasi-one-dimensional hydrogen-bonded structure that exhibits only two hydrogen bonds per water molecule. These structures consist of strongly hydrogen-bonded linear chains of water molecules that zig-zag along one dimension, stabilized by van der Waals interactions that stack these chains along the other dimension. The unusual interplay of hydrogen bonding and van der Waals interactions in nanoconfined ice results in atypical proton behavior such as potential ferroelectric behavior, low dielectric response, and long-range proton dynamics.

Topics & Concepts

van der Waals forceHydrogen bondChemical physicsMoleculeProtonMaterials scienceHydrogenIce crystalsStack (abstract data type)Molecular dynamicsIce IhCrystallographyChemistryComputational chemistryPhysicsQuantum mechanicsComputer scienceOrganic chemistryProgramming languageOpticsMaterial Dynamics and PropertiesElectrostatics and Colloid InteractionsMethane Hydrates and Related Phenomena
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