DPA-2: Towards a universal large atomic model for molecular and materials simulation

Wang, Han; Zhang, Duo; Liu, Xinzijian; Zhang, Xiangyu; Zhang, Chengqian; Cai, Chun; Bi, Hangrui; Du, Yiming; Qin, Xuejian; Huang, Jiameng; Li, Bowen; Shan, Yifan; Zeng, Jinzhe; Zhang, Yuzhi; Liu, Siyuan; Li, Yifan; Chang, Junhan; Wang, Xinyan; Zhou, Shuo; Liu, Jianchuan; Luo, Xiaoshan; Wang, Zhenyu; Jiang, Wanrun; Wu, Jing; Yang, Yudi; Yang, Jiyuan; Yang, Manyi; Gong, Fu-Qiang; Zhang, Linshuang; Shi, Mengchao; Dai, Fu-Zhi; York, Darrin; Liu, Shi; Zhu, Tong; Zhong, Zhicheng; Lv, Jian; Cheng, Jun; Jia, Weile; Chen, Mohan; Ke, Guolin; E, Weinan; Zhang, Linfeng

doi:10.21203/rs.3.rs-4100052/v1

2024

DOI: 10.21203/rs.3.rs-4100052/v1

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DPA-2: Towards a universal large atomic model for molecular and materials simulation

Han Wang,

Duo Zhang,

Xinzijian Liu

et al.

Abstract: The rapid development of artificial intelligence (AI) is driving significant changes in the field of atomic modeling, simulation, and design. AI-based potential energy models have been successfully used to perform large-scale and long-time simulations with the accuracy of ab initio electronic structure methods. However, the model generation process still hinders applications at scale. We envision that the next stage would be a model-centric ecosystem, in which a large atomic model (LAM), pre-trained with as ma… Show more

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Cited by 5 publications

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Insights into Lithium Sulfide Glass Electrolyte Structures and Ionic Conductivity via Machine Learning Force Field Simulations

Zhou,

Luo,

Martin

et al. 2024

ACS Appl. Mater. Interfaces

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Sulfide-based solid electrolytes (SEs) are important for advancing all-solid-state batteries (ASSBs), primarily due to their high ionic conductivities and robust mechanical stability. Glassy SEs (GSEs) comprising mixed Si and P glass formers are particularly promising for their synthesis process and their ability to prevent lithium dendrite growth. However, to date, the complexity of their glassy structures hinders a complete understanding of the relationships between their structures and properties. This study introduces a new machine learning force field (ML-FF) tailored for lithium sulfide-based GSEs, enabling the exploration of their structural characteristics, mechanical properties, and lithium ionic conductivities. Using molecular dynamic (MD) simulations with this ML-FF, we explore the glass structures in varying compositions, including binary Li 2 S−SiS 2 and Li 2 S− P 2 S 5 as well as ternary Li 2 S−SiS 2 −P 2 S 5 . Our simulations yielded consistent results in terms of density, elastic modulus, radial distribution functions, and neutron structure factors compared to DFT and experimental work. Our findings reveal distinct local environments for Si and P within these glasses, with most Si atoms in edge-sharing configurations in Li 2 S−SiS 2 and a mix of cornerand edge-sharing tetrahedra in the ternary Li 2 S−SiS 2 −P 2 S 5 composition. For lithium ionic conductivity at 300 K, the 50Li 2 S−50SiS 2 glass displayed the lowest conductivity at 2.1 mS/cm, while the 75Li 2 S−25P 2 S 5 composition exhibited the highest conductivity at 3.6 mS/cm. The ternary glass showed a conductivity of 2.6 mS/cm, sitting between the two. Moreover, an in-depth analysis of lithium ion diffusion over the MD trajectory in the ternary glass demonstrated a significant correlation between diffusion pathways and the rotational dynamics of nearby SiS 4 or PS 4 tetrahedra. The ML-FF developed in this study provides an important tool for exploring a broad spectrum of solid-state and mixed former sulfide-based electrolytes.

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Insights into Lithium Sulfide Glass Electrolyte Structures and Ionic Conductivity via Machine Learning Force Field Simulations

Zhou,

Luo,

Martin

et al. 2024

ACS Appl. Mater. Interfaces

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Deep learning generative model for crystal structure prediction

Luo,

Wang,

Gao

et al. 2024

npj Comput Mater

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Recent advances in deep learning generative models (GMs) have created high capabilities in accessing and assessing complex high-dimensional data, allowing superior efficiency in navigating vast material configuration space in search of viable structures. Coupling such capabilities with physically significant data to construct trained models for materials discovery is crucial to moving this emerging field forward. Here, we present a universal GM for crystal structure prediction (CSP) via a conditional crystal diffusion variational autoencoder (Cond-CDVAE) approach, which is tailored to allow user-defined material and physical parameters such as composition and pressure. This model is trained on an expansive dataset containing over 670,000 local minimum structures, including a rich spectrum of high-pressure structures, along with ambient-pressure structures in Materials Project database. We demonstrate that the Cond-CDVAE model can generate physically plausible structures with high fidelity under diverse pressure conditions without necessitating local optimization, accurately predicting 59.3% of the 3547 unseen ambient-pressure experimental structures within 800 structure samplings, with the accuracy rate climbing to 83.2% for structures comprising fewer than 20 atoms per unit cell. These results meet or exceed those achieved via conventional CSP methods based on global optimization. The present findings showcase substantial potential of GMs in the realm of CSP.

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Transfer learning for accurate description of atomic transport in Al–Cu melts

Khazieva,

Chtchelkatchev,

Ryltsev

2024

The Journal of Chemical Physics

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Machine learning interatomic potentials (MLIPs) provide an optimal balance between accuracy and computational efficiency and allow studying problems that are hardly solvable by traditional methods. For metallic alloys, MLIPs are typically developed based on density functional theory with generalized gradient approximation (GGA) for the exchange–correlation functional. However, recent studies have shown that this standard protocol can be inaccurate for calculating the transport properties or phase diagrams of some metallic alloys. Thus, optimization of the choice of exchange–correlation functional and specific calculation parameters is needed. In this study, we address this issue for Al–Cu alloys, in which standard Perdew–Burke–Ernzerhof (PBE)-based MLIPs cannot accurately calculate the viscosity and melting temperatures at Cu-rich compositions. We have built MLIPs based on different exchange–correlation functionals, including meta-GGA, using a transfer learning strategy, which allows us to reduce the amount of training data by an order of magnitude compared to a standard approach. We show that r2SCAN- and PBEsol-based MLIPs provide much better accuracy in describing thermodynamic and transport properties of Al–Cu alloys. In particular, r2SCAN-based deep machine learning potential allows us to quantitatively reproduce the concentration dependence of dynamic viscosity. Our findings contribute to the development of MLIPs that provide quantum chemical accuracy, which is one of the most challenging problems in modern computational materials science.

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DPA-2: Towards a universal large atomic model for molecular and materials simulation

Cited by 5 publications

References 72 publications

Insights into Lithium Sulfide Glass Electrolyte Structures and Ionic Conductivity via Machine Learning Force Field Simulations

Insights into Lithium Sulfide Glass Electrolyte Structures and Ionic Conductivity via Machine Learning Force Field Simulations

Deep learning generative model for crystal structure prediction

Transfer learning for accurate description of atomic transport in Al–Cu melts

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