One-dimensional <i>vs.</i> two-dimensional proton transport processes at solid–liquid zinc-oxide–water interfaces

Hellström, Matti; Quaranta, Vanessa; Behler, Jörg

doi:10.1039/c8sc03033b

Cited by 55 publications

(76 citation statements)

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“…Several authors have demonstrated the DNNs' ability to reproduce the complex PES of ab initio potentials, [32][33][34] thus allowing accurate long-time simulations of several condensed phase systems [35][36][37] including metal oxide-water interfaces. 38,39 In the present study, the ab initio-based DNN potential reproduces energy and atomic forces obtained from DFT at a ve orders of magnitude lower computational cost. This allows us to carry out MD simulations at the nanosecond timescale on systems of thousands of atoms and to use enhanced sampling techniques to obtain converged free energy surfaces of proton transfer at the aqueous anatase (101) interface as a function of suitable reaction coordinates.…”

Section: Introductionmentioning

confidence: 85%

Free energy of proton transfer at the water–TiO₂ interface from ab initio deep potential molecular dynamics

et al. 2020

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Section: Introductionmentioning

confidence: 85%

Free energy of proton transfer at the water–TiO₂ interface from ab initio deep potential molecular dynamics

et al. 2020

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“…In the condensed phase, water molecules organize themselves into large cluster structures, strongly connected by hydrogen-bond networks [25,26]. Frequently (aqueous) solvated semiconductor surfaces sustain and enhance the formation of such networks [11,[27][28][29][30], resulting in the ordered formation of surface chains of water molecules. Thus the very well-developed network of H bonds in water plays a fundamental role in not only defining its structural and dynamical properties but also the properties of the material it interacts with [31,32].…”

Section: Introductionmentioning

confidence: 99%

Proton-transfer dynamics in ionized water chains using real-time time-dependent density functional theory

Sharma

Fernández-Serra

2020

Phys. Rev. Research

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In density functional-theoretic studies of photoionized water-based systems, the role of charge localization in proton-transfer dynamics is not well understood. This is due to the inherent complexity in extracting the contributions of coupled electron-nuclear nonadiabatic dynamics in the presence of exchange and correlation functional errors. In this work we address this problem by simulating a model system of ionized linear Hbonded water clusters using real-time time-dependent density functional theory-based Ehrenfest dynamics. Our aim is to understand how self-interaction error in semilocal exchange and correlation functionals affects the probability of proton transfer. In particular, we show that the proton-transfer probability is largely underestimated for short H-bonded chains but becomes comparable to that predicted by hybrid functionals for (H 2 O) + n chains with n > 3. This is because the formation of hemibonded-type geometries is largely suppressed in extended H-bonded structures. We also show how the degree of localization of the initial photo-hole is connected to the probability of a proton-transfer reaction, as well as to the hole-proton separation. These results are compared to those obtained with adiabatic dynamics where the initial wave function is allowed to relax to the ground state of the ion cluster, explaining why different functionals and dynamical approaches lead to quantitatively different results.

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“…Copyright (2017) American Chemical Society.) differs from that over ZnO (1010) [98] and also investigated in further detail the structure of the water near ZnO surfaces [99].…”

Section: Transport At Surfaces Interfaces and In Amorphous Phasesmentioning

confidence: 99%

Machine learning for the modeling of interfaces in energy storage and conversion materials

Artrith

2019

J. Phys. Energy

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The properties and atomic-scale dynamics of interfaces play an important role for the performance of energy storage and conversion devices such as batteries and fuel cells. In this topical review, we consider recent progress in machine-learning (ML) approaches for the computational modeling of materials interfaces. ML models are computationally much more efficient than first principles methods and thus allow to model larger systems and extended timescales, a necessary prerequisites for the accurate description of many interface properties. Here we review the recent major developments of ML-based interatomic potentials for atomistic modeling and ML approaches for the direct prediction of materials properties. This is followed by a discussion of ML applications to solid-gas, solid-liquid, and solid-solid interfaces as well as to nanostructured and amorphous phases that commonly form in interface regions. We then highlight how ML has been used to obtain important insights into the structure and stability of interfaces, interfacial reactions, and mass transport at interfaces. Finally, we offer a perspective on the current state of ML potential development and identify future directions and opportunities for this exciting research field.

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One-dimensional vs. two-dimensional proton transport processes at solid–liquid zinc-oxide–water interfaces

Abstract: Neural network molecular dynamics simulations unravel the long-range proton transport properties of ZnO–water interfaces.

Cited by 55 publications

References 53 publications

Free energy of proton transfer at the water–TiO₂ interface from ab initio deep potential molecular dynamics

Free energy of proton transfer at the water–TiO₂ interface from ab initio deep potential molecular dynamics

Proton-transfer dynamics in ionized water chains using real-time time-dependent density functional theory

Machine learning for the modeling of interfaces in energy storage and conversion materials

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One-dimensional vs. two-dimensional proton transport processes at solid–liquid zinc-oxide–water interfaces

Abstract: Neural network molecular dynamics simulations unravel the long-range proton transport properties of ZnO–water interfaces.

Cited by 55 publications

References 53 publications

Free energy of proton transfer at the water–TiO2 interface from ab initio deep potential molecular dynamics

Free energy of proton transfer at the water–TiO2 interface from ab initio deep potential molecular dynamics

Proton-transfer dynamics in ionized water chains using real-time time-dependent density functional theory

Machine learning for the modeling of interfaces in energy storage and conversion materials

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Product

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About

Free energy of proton transfer at the water–TiO₂ interface from ab initio deep potential molecular dynamics

Free energy of proton transfer at the water–TiO₂ interface from ab initio deep potential molecular dynamics