Litcius/Paper detail

Modeling the aqueous interface of amorphous TiO2 using deep potential molecular dynamics

Zhutian Ding, Annabella Selloni

2023The Journal of Chemical Physics17 citationsDOIOpen Access PDF

Abstract

Amorphous titanium dioxide (a-TiO2) is widely used as a coating material in applications such as electrochemistry and self-cleaning surfaces where its interface with water has a central role. However, little is known about the structures of the a-TiO2 surface and aqueous interface, particularly at the microscopic level. In this work, we construct a model of the a-TiO2 surface via a cut-melt-and-quench procedure based on molecular dynamics simulations with deep neural network potentials (DPs) trained on density functional theory data. After interfacing the a-TiO2 surface with water, we investigate the structure and dynamics of the resulting system using a combination of DP-based molecular dynamics (DPMD) and ab initio molecular dynamics (AIMD) simulations. Both AIMD and DPMD simulations reveal that the distribution of water on the a-TiO2 surface lacks distinct layers normally found at the aqueous interface of crystalline TiO2, leading to an ∼10 times faster diffusion of water at the interface. Bridging hydroxyls (Ti2-ObH) resulting from water dissociation decay several times more slowly than terminal hydroxyls (Ti-OwH) due to fast Ti-OwH2 → Ti-OwH proton exchange events. These results provide a basis for a detailed understanding of the properties of a-TiO2 in electrochemical environments. Moreover, the procedure of generating the a-TiO2-interface employed here is generally applicable to studying the aqueous interfaces of amorphous metal oxides.

Topics & Concepts

Molecular dynamicsAmorphous solidAqueous solutionMaterials scienceChemical physicsBridging (networking)NanotechnologyChemistryComputational chemistryPhysical chemistryCrystallographyComputer scienceComputer networkElectrochemical Analysis and ApplicationsMachine Learning in Materials ScienceSpectroscopy and Quantum Chemical Studies