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

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

doi:10.1038/s41467-024-54554-x

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

Keke Song
, Rui Zhao
, Jiahui Liu
, Yanzhou Wang
, Eric Lindgren
, Yong Wang
, Shunda Chen
, Ke Xu
, Ting Liang
, Penghua Ying
, Nan Xu
, Zhiqiang Zhao
, Jiuyang Shi
, Junjie Wang
, Shuang Lyu
, Zezhu Zeng
, Shirong Liang
, Haikuan Dong
, Ligang Sun
, Yue Chen

Zhuhua Zhang, Wanlin Guo, Ping Qian, Jian Sun, Paul Erhart, Tapio Ala-Nissila, Yanjing Su, Zheyong Fan

Research output: Contribution to journal › Article › peer-review

112 Scopus citations

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 employing one-component and two-component systems suffices. Our unified UNEP-v1 model exhibits superior performance across various physical properties compared to a widely used embedded-atom method potential, while maintaining remarkable efficiency. We demonstrate our approach’s effectiveness through reproducing experimentally observed chemical order and stable phases, and large-scale simulations of plasticity and primary radiation damage in MoTaVW alloys.

Original language	English
Article number	10208
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-54554-x
State	Published - Dec 2024
Externally published	Yes

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Song, K., Zhao, R., Liu, J., Wang, Y., Lindgren, E., Wang, Y., Chen, S., Xu, K., Liang, T., Ying, P., Xu, N., Zhao, Z., Shi, J., Wang, J., Lyu, S., Zeng, Z., Liang, S., Dong, H., Sun, L., ... Fan, Z. (2024). General-purpose machine-learned potential for 16 elemental metals and their alloys. Nature Communications, 15(1), Article 10208. https://doi.org/10.1038/s41467-024-54554-x

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title = "General-purpose machine-learned potential for 16 elemental metals and their alloys",

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 employing one-component and two-component systems suffices. Our unified UNEP-v1 model exhibits superior performance across various physical properties compared to a widely used embedded-atom method potential, while maintaining remarkable efficiency. We demonstrate our approach{\textquoteright}s effectiveness through reproducing experimentally observed chemical order and stable phases, and large-scale simulations of plasticity and primary radiation damage in MoTaVW alloys.",

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

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

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doi = "10.1038/s41467-024-54554-x",

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Song, K, Zhao, R, Liu, J, Wang, Y, Lindgren, E, Wang, Y, Chen, S, Xu, K, Liang, T, Ying, P, Xu, N, Zhao, Z, Shi, J, Wang, J, Lyu, S, Zeng, Z, Liang, S, Dong, H, Sun, L, Chen, Y, Zhang, Z, Guo, W, Qian, P, Sun, J, Erhart, P, Ala-Nissila, T, Su, Y & Fan, Z 2024, 'General-purpose machine-learned potential for 16 elemental metals and their alloys', Nature Communications, vol. 15, no. 1, 10208. https://doi.org/10.1038/s41467-024-54554-x

TY - JOUR

T1 - General-purpose machine-learned potential for 16 elemental metals and their alloys

AU - Song, Keke

AU - Zhao, Rui

AU - Liu, Jiahui

AU - Wang, Yanzhou

AU - Lindgren, Eric

AU - Wang, Yong

AU - Chen, Shunda

AU - Xu, Ke

AU - Liang, Ting

AU - Ying, Penghua

AU - Xu, Nan

AU - Zhao, Zhiqiang

AU - Shi, Jiuyang

AU - Wang, Junjie

AU - Lyu, Shuang

AU - Zeng, Zezhu

AU - Liang, Shirong

AU - Dong, Haikuan

AU - Sun, Ligang

AU - Chen, Yue

AU - Zhang, Zhuhua

AU - Guo, Wanlin

AU - Qian, Ping

AU - Sun, Jian

AU - Erhart, Paul

AU - Ala-Nissila, Tapio

AU - Su, Yanjing

AU - Fan, Zheyong

PY - 2024/12

Y1 - 2024/12

N2 - 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 employing one-component and two-component systems suffices. Our unified UNEP-v1 model exhibits superior performance across various physical properties compared to a widely used embedded-atom method potential, while maintaining remarkable efficiency. We demonstrate our approach’s effectiveness through reproducing experimentally observed chemical order and stable phases, and large-scale simulations of plasticity and primary radiation damage in MoTaVW alloys.

AB - 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 employing one-component and two-component systems suffices. Our unified UNEP-v1 model exhibits superior performance across various physical properties compared to a widely used embedded-atom method potential, while maintaining remarkable efficiency. We demonstrate our approach’s effectiveness through reproducing experimentally observed chemical order and stable phases, and large-scale simulations of plasticity and primary radiation damage in MoTaVW alloys.

UR - https://www.scopus.com/pages/publications/85210078572

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DO - 10.1038/s41467-024-54554-x

M3 - 文章

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AN - SCOPUS:85210078572

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 10208

ER -

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

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