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Main Authors: Di Pino, Solana, Donkor, Edward Danquah, Sánchez, Verónica M., Rodriguez, Alex, Cassone, Giuseppe, Scherlis, Damian, Hassanali, Ali
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2308.15319
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author Di Pino, Solana
Donkor, Edward Danquah
Sánchez, Verónica M.
Rodriguez, Alex
Cassone, Giuseppe
Scherlis, Damian
Hassanali, Ali
author_facet Di Pino, Solana
Donkor, Edward Danquah
Sánchez, Verónica M.
Rodriguez, Alex
Cassone, Giuseppe
Scherlis, Damian
Hassanali, Ali
contents The structure of the excess proton in liquid water has been the subject of lively debate from both experimental and theoretical fronts for the last century. Fluctuations of the proton are typically interpreted in terms of limiting states referred to as the Eigen and Zundel species. Here we put these ideas under the microscope taking advantage of recent advances in unsupervised learning that use local atomic descriptors to characterize environments of acidic water combined with advanced clustering techniques. Our agnostic approach leads to the observation of only a single charged cluster and two neutral ones. We demonstrate that the charged cluster involving the excess proton, is best seen as an ionic topological defect in water's hydrogen bond network forming a single local minimum on the global free-energy landscape. This charged defect is a highly fluxional moiety where the idealized Eigen and Zundel species are neither limiting configurations nor distinct thermodynamic states. Instead, the ionic defect enhances the presence of neutral water defects through strong interactions with the network. We dub the combination of the charged and neutral defect clusters as ZundEig demonstrating that the fluctuations between these local environments provide a general framework for rationalizing more descriptive notions of the proton in the existing literature.
format Preprint
id arxiv_https___arxiv_org_abs_2308_15319
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle ZundEig: The Structure of the Proton in Liquid Water From Unsupervised Learning
Di Pino, Solana
Donkor, Edward Danquah
Sánchez, Verónica M.
Rodriguez, Alex
Cassone, Giuseppe
Scherlis, Damian
Hassanali, Ali
Materials Science
The structure of the excess proton in liquid water has been the subject of lively debate from both experimental and theoretical fronts for the last century. Fluctuations of the proton are typically interpreted in terms of limiting states referred to as the Eigen and Zundel species. Here we put these ideas under the microscope taking advantage of recent advances in unsupervised learning that use local atomic descriptors to characterize environments of acidic water combined with advanced clustering techniques. Our agnostic approach leads to the observation of only a single charged cluster and two neutral ones. We demonstrate that the charged cluster involving the excess proton, is best seen as an ionic topological defect in water's hydrogen bond network forming a single local minimum on the global free-energy landscape. This charged defect is a highly fluxional moiety where the idealized Eigen and Zundel species are neither limiting configurations nor distinct thermodynamic states. Instead, the ionic defect enhances the presence of neutral water defects through strong interactions with the network. We dub the combination of the charged and neutral defect clusters as ZundEig demonstrating that the fluctuations between these local environments provide a general framework for rationalizing more descriptive notions of the proton in the existing literature.
title ZundEig: The Structure of the Proton in Liquid Water From Unsupervised Learning
topic Materials Science
url https://arxiv.org/abs/2308.15319