A Multiple-Fidelity Method for Accurate Simulation of MoS 2 Properties Using JAX-ReaxFF and Neural Network Potentials.
Kehan WangLongkun XuWei ShaoHaishun JinQiang WangMing MaPublished in: The journal of physical chemistry letters (2024)
Reactive force field (ReaxFF) is a commonly used force field for modeling chemical reactions at the atomic level. Recently, JAX-ReaxFF, combined with automatic differentiation, has been used to efficiently parametrize ReaxFF. However, its analytical formula may lead to inaccurate predictions. While neural network-based potentials (NNPs) trained on density functional theory-labeled data offer a more accurate method, it requires a large amount of training data to be trained from scratch. To overcome these issues, we present a multiple-fidelity method that combines JAX-ReaxFF and NNP and apply the method on MoS 2 , a promising two-dimensional semiconductor for flexible electronics. By incorporating implicit prior physical information, ReaxFF can serve as a cost-effective way to generate pretraining data, facilitating more accurate simulations of MoS 2 . Moreover, in the Mo-S-H system, the pretraining strategy can reduce root-mean-square errors of energy by 20%. This approach can be extended to a wide variety of material systems, accelerating their computational research.
Keyphrases
- neural network
- molecular dynamics simulations
- density functional theory
- electronic health record
- room temperature
- quantum dots
- high resolution
- molecular dynamics
- big data
- physical activity
- single molecule
- resistance training
- mental health
- machine learning
- emergency department
- data analysis
- deep learning
- preterm infants
- health information
- social media
- drug induced
- preterm birth
- liquid chromatography
- adverse drug