Zhou, J., Fu, Y., Liu, L., & Liu, C. (2024). Constant-Potential Machine Learning Molecular Dynamics Simulations Reveal Potential-Regulated Cu Cluster Formation on MoS2. arXiv preprint arXiv:2411.14732.
This research paper aims to introduce a new machine learning force field model, EEP-MLFF, capable of simulating electrochemical processes and apply it to investigate the potential-dependent formation of copper clusters on a MoS2 surface.
The researchers developed the EEP-MLFF model by integrating electric potential as an explicit input parameter in an atomic neural network. They trained and validated the model using data from ab initio molecular dynamics (AIMD) simulations of a Cu/MoS2 system under various electric potentials. They then performed constant-potential molecular dynamics (CP-MLMD) simulations using the EEP-MLFF to study the aggregation behavior of Cu atoms on the MoS2 surface at different potentials.
The EEP-MLFF model provides an efficient and accurate method for simulating electrochemical processes. The study demonstrates that electric potential can be used to control the formation of catalytically active single-atom clusters on a substrate, offering a potential route for synthesizing efficient electrocatalysts.
This research contributes to the field of electrocatalysis by providing a powerful tool for simulating and understanding electrochemical processes at the atomic level. The findings have implications for designing and optimizing single-atom and single-cluster catalysts for various applications.
The study focuses on a specific system (Cu/MoS2) and a limited range of potentials. Further research could explore the applicability of the EEP-MLFF model to other electrochemical systems and investigate the influence of factors like electrolyte composition and temperature on cluster formation.
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by Jingwen Zhou... klokken arxiv.org 11-25-2024
https://arxiv.org/pdf/2411.14732.pdfDypere Spørsmål