What question did this study set out to answer?

This research aims to explore the dynamics of sulfur vacancies in MoS2 and their implications for catalytic activity.

February 19, 2026Open Access

Large‐Scale Cooperative Sulfur Vacancy Dynamics in Two‐Dimensional Mos 2 From Machine Learning Interatomic Potentials

Key Points

This research aims to explore the dynamics of sulfur vacancies in MoS2 and their implications for catalytic activity.
Conducted nanosecond-scale molecular dynamics simulations
Utilized machine learning interatomic potentials for accurate modeling
Analyzed vacancy incorporation into clusters of varying sizes
Compared two MLIP frameworks for effectiveness in simulations
Identified key mechanisms of cooperative vacancy transport in MoS2
Explained experimentally observed irradiation-induced vacancy patterns
Noted formation of line defects spanning tens of nanometers
Showed differences in results between the two MLIP frameworks used

Abstract

ABSTRACT The formation of extended sulfur vacancies in MoS 2 monolayers is closely associated with catalytic activity and may also be the basis for its memristive behavior. Nanosecond‐scale molecular dynamics simulations using machine learning interatomic potentials (MLIPs) reveal key mechanisms of cooperative vacancy transport, including incorporation of vacancies into clusters of arbitrary size. The simulations provide a coherent atomistic explanation for irradiation‐induced vacancy patterns observed experimentally, especially the formation of line defects spanning tens of nanometers. Results and performance are compared of two MLIP frameworks: (i) on‐the‐fly learning with Gaussian approximation potential, and (ii) fine‐tuning of an equivariant foundation model.

Large‐Scale Cooperative Sulfur Vacancy Dynamics in Two‐Dimensional Mos 2 From Machine Learning Interatomic Potentials

Key Points

Abstract

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