General-purpose machine-learned potential for 16 elemental metals and their alloys

Song, Keke; Zhao, Rui; Liu, Jiahui; Wang, Yanzhou; Lindgren, Eric; Wang, Yong; Chen, Shunda; Xu, Ke; Liang, Ting; Ying, Penghua; Xu, Nan; Zhao, Zhiqiang; Shi, Jiuyang; Wang, Junjie; Lyu, Shuang; Zeng, Zezhu; Liang, Shirong; Dong, Haikuan; Sun, Ligang; Chen, Yue; Zhang, Zhuhua; Guo, Wanlin; Qian, Ping; Sun, Jian; Erhart, Paul; Ala-Nissila, Tapio; Su, Yanjing; Fan, Zheyong

doi:10.1038/s41467-024-54554-x

Nat Commun

2024

DOI: 10.1038/s41467-024-54554-x

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General-purpose machine-learned potential for 16 elemental metals and their alloys

Keke Song,

Rui Zhao,

Jiahui Liu

et al.

Abstract: Machine-learned potentials (MLPs) have exhibited remarkable accuracy, yet the lack of general-purpose MLPs for a broad spectrum of elements and their alloys limits their applicability. Here, we present a promising approach for constructing a unified general-purpose MLP for numerous elements, demonstrated through a model (UNEP-v1) for 16 elemental metals and their alloys. To achieve a complete representation of the chemical space, we show, via principal component analysis and diverse test datasets, that employi… Show more

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Cited by 3 publications

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Predicting Mechanical and Thermal Properties of High‐Entropy Ceramics via Transferable Machine‐Learning‐Potential‐Based Molecular Dynamics

Liu,

Meng,

Zhu

et al. 2024

Adv Funct Materials

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The mechanical and thermal performance of high‐entropy ceramics are critical to their use in extreme conditions. However, the vast composition space of high‐entropy ceramics significantly hinders their development with desired mechanical and thermal properties. Herein, taking high‐entropy carbides (HECs) as the model, the efficiency and effectiveness of predicting mechanical and thermal properties via transferable machine‐learning‐potential‐based molecular dynamics (MD) have been demonstrated. Specifically, a transferable neuroevolution potential (NEP) with broad compositional applicability for HECs of ten transition metal elements from group IIIB‐VIB is efficiently constructed from the small dataset comprising unary and binary carbides with an equal amount of ergodic chemical compositions. Based on this well‐established transferable NEP, MD predictions on mechanical and thermal properties of different HECs have shown good agreement with the results of first‐principles calculations and experimental measurements, validating the accuracy, transferability, and reliability of using the transferable machine‐learning‐potential‐based MD simulations in investigating mechanical and thermal performance of HECs. This work provides a strategy to accelerate the search for high‐entropy ceramics with desirable mechanical and thermal properties.

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Predicting Mechanical and Thermal Properties of High‐Entropy Ceramics via Transferable Machine‐Learning‐Potential‐Based Molecular Dynamics

Liu,

Meng,

Zhu

et al. 2024

Adv Funct Materials

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Impact of Lithium Nonstoichiometry on Ionic Diffusion in Tetragonal Garnet-Type Li₇La₃Zr₂O₁₂

Yan,

Zhu

2024

Chem. Mater.

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Understanding ion transport mechanisms on the atomistic scale in solid-state electrolytes is crucial for the development of all-solid-state batteries. Li 7 La 3 Zr 2 O 12 (LLZO) is a promising oxide solid electrolyte material, whose phase transition behavior and ion transport mechanisms have attracted significant research attention. Previous studies have primarily focused on ion transport in the cubic phase (intrinsic high-temperature phase or doped variants). In contrast, the tetragonal phase of LLZO, despite its close relationship with the cubic phase, has received less attention due to its relatively low ionic conductivity and high computational cost. A few recent computational studies have shown significant discrepancies in conductivity and activation energy between calculated and experimental values. Therefore, the unclear ion transport mechanisms in the tetragonal phase of LLZO are critical to understanding and designing oxide solid electrolytes. In this study, we employ state-of-the-art machine-learning-based neuroevolution potential molecular dynamics simulations to investigate the effects of lithium nonstoichiometry on the ionic conductivity and phase stability of LLZO. We demonstrate that small deviations from stoichiometry, particularly lithium deficiency, dramatically reduce the activation energy for Li + diffusion in tetragonal LLZO from 1.227 to 0.425 eV, increasing room-temperature ionic conductivity by 10 orders of magnitude. The slight lithium nonstoichiometry, which commonly occurs during high-temperature synthesis, has a significant effect on ion transport in the tetragonal phase. Our findings highlight the crucial role of lithium nonstoichiometry and defect chemistry in enhancing LLZO performance and provide insights for the rational design of high-performance solid electrolytes through defect engineering.

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Machine Learning Advances in High-Entropy Alloys: A Mini-Review

Sun,

2024

Entropy

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The efficacy of machine learning has increased exponentially over the past decade. The utilization of machine learning to predict and design materials has become a pivotal tool for accelerating materials development. High-entropy alloys are particularly intriguing candidates for exemplifying the potency of machine learning due to their superior mechanical properties, vast compositional space, and intricate chemical interactions. This review examines the general process of developing machine learning models. The advances and new algorithms of machine learning in the field of high-entropy alloys are presented in each part of the process. These advances are based on both improvements in computer algorithms and physical representations that focus on the unique ordering properties of high-entropy alloys. We also show the results of generative models, data augmentation, and transfer learning in high-entropy alloys and conclude with a summary of the challenges still faced in machine learning high-entropy alloys today.

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General-purpose machine-learned potential for 16 elemental metals and their alloys

Cited by 3 publications

References 83 publications

Predicting Mechanical and Thermal Properties of High‐Entropy Ceramics via Transferable Machine‐Learning‐Potential‐Based Molecular Dynamics

Predicting Mechanical and Thermal Properties of High‐Entropy Ceramics via Transferable Machine‐Learning‐Potential‐Based Molecular Dynamics

Impact of Lithium Nonstoichiometry on Ionic Diffusion in Tetragonal Garnet-Type Li₇La₃Zr₂O₁₂

Machine Learning Advances in High-Entropy Alloys: A Mini-Review

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Resources

About

General-purpose machine-learned potential for 16 elemental metals and their alloys

Cited by 3 publications

References 83 publications

Predicting Mechanical and Thermal Properties of High‐Entropy Ceramics via Transferable Machine‐Learning‐Potential‐Based Molecular Dynamics

Predicting Mechanical and Thermal Properties of High‐Entropy Ceramics via Transferable Machine‐Learning‐Potential‐Based Molecular Dynamics

Impact of Lithium Nonstoichiometry on Ionic Diffusion in Tetragonal Garnet-Type Li7La3Zr2O12

Machine Learning Advances in High-Entropy Alloys: A Mini-Review

Contact Info

Product

Resources

About

Impact of Lithium Nonstoichiometry on Ionic Diffusion in Tetragonal Garnet-Type Li₇La₃Zr₂O₁₂