Machine learning accelerated carbon neutrality research using big data—from predictive models to interatomic potentials

Ling Jun Wu; Zhen Ming Xu; Zi Xuan Wang; Zi Jian Chen; Zhi Chao Huang; Chao Peng; Xiang Dong Pei; Xiang Guo Li; Jonathan P. Mailoa; Chang Yu Hsieh; Tao Wu; Xue Feng Yu; Hai Tao Zhao

doi:10.1007/s11431-022-2095-7

Machine learning accelerated carbon neutrality research using big data—from predictive models to interatomic potentials

Ling Jun Wu, Zhen Ming Xu, Zi Xuan Wang, Zi Jian Chen, Zhi Chao Huang, Chao Peng, Xiang Dong Pei, Xiang Guo Li, Jonathan P. Mailoa, Chang Yu Hsieh, Tao Wu, Xue Feng Yu, Hai Tao Zhao

Department of Chemical and Environmental Engineering

Research output: Journal Publication › Review article › peer-review

1 Citation (Scopus)

Abstract

Carbon neutrality has been proposed as a solution for the current severe energy and climate crisis caused by the overuse of fossil fuels, and machine learning (ML) has exhibited excellent performance in accelerating related research owing to its powerful capacity for big data processing. This review presents a detailed overview of ML accelerated carbon neutrality research with a focus on energy management, screening of novel energy materials, and ML interatomic potentials (MLIPs), with illustrations of two selected MLIP algorithms: moment tensor potential (MTP) and neural equivariant interatomic potential (NequIP). We conclude by outlining the important role of ML in accelerating the achievement of carbon neutrality from global-scale energy management, unprecedented screening of advanced energy materials in massive chemical space, to the revolution of atomic-scale simulations of MLIPs, which has the bright prospect of applications.

Original language	English
Pages (from-to)	2274-2296
Number of pages	23
Journal	Science China Technological Sciences
Volume	65
Issue number	10
DOIs	https://doi.org/10.1007/s11431-022-2095-7
Publication status	Published - Oct 2022

Keywords

big data
carbon neutrality
interatomic potentials
machine learning
molecular dynamics

ASJC Scopus subject areas

General Materials Science
General Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1007/s11431-022-2095-7

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Wu, L. J., Xu, Z. M., Wang, Z. X., Chen, Z. J., Huang, Z. C., Peng, C., Pei, X. D., Li, X. G., Mailoa, J. P., Hsieh, C. Y., Wu, T., Yu, X. F., & Zhao, H. T. (2022). Machine learning accelerated carbon neutrality research using big data—from predictive models to interatomic potentials. Science China Technological Sciences, 65(10), 2274-2296. https://doi.org/10.1007/s11431-022-2095-7

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title = "Machine learning accelerated carbon neutrality research using big data—from predictive models to interatomic potentials",

abstract = "Carbon neutrality has been proposed as a solution for the current severe energy and climate crisis caused by the overuse of fossil fuels, and machine learning (ML) has exhibited excellent performance in accelerating related research owing to its powerful capacity for big data processing. This review presents a detailed overview of ML accelerated carbon neutrality research with a focus on energy management, screening of novel energy materials, and ML interatomic potentials (MLIPs), with illustrations of two selected MLIP algorithms: moment tensor potential (MTP) and neural equivariant interatomic potential (NequIP). We conclude by outlining the important role of ML in accelerating the achievement of carbon neutrality from global-scale energy management, unprecedented screening of advanced energy materials in massive chemical space, to the revolution of atomic-scale simulations of MLIPs, which has the bright prospect of applications.",

keywords = "big data, carbon neutrality, interatomic potentials, machine learning, molecular dynamics",

author = "Wu, {Ling Jun} and Xu, {Zhen Ming} and Wang, {Zi Xuan} and Chen, {Zi Jian} and Huang, {Zhi Chao} and Chao Peng and Pei, {Xiang Dong} and Li, {Xiang Guo} and Mailoa, {Jonathan P.} and Hsieh, {Chang Yu} and Tao Wu and Yu, {Xue Feng} and Zhao, {Hai Tao}",

note = "Publisher Copyright: {\textcopyright} 2022, Science China Press and Springer-Verlag GmbH Germany, part of Springer Nature.",

year = "2022",

month = oct,

doi = "10.1007/s11431-022-2095-7",

language = "English",

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journal = "Science China Technological Sciences",

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AU - Wu, Ling Jun

AU - Xu, Zhen Ming

AU - Wang, Zi Xuan

AU - Chen, Zi Jian

AU - Huang, Zhi Chao

AU - Peng, Chao

AU - Pei, Xiang Dong

AU - Li, Xiang Guo

AU - Mailoa, Jonathan P.

AU - Hsieh, Chang Yu

AU - Wu, Tao

AU - Yu, Xue Feng

AU - Zhao, Hai Tao

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N2 - Carbon neutrality has been proposed as a solution for the current severe energy and climate crisis caused by the overuse of fossil fuels, and machine learning (ML) has exhibited excellent performance in accelerating related research owing to its powerful capacity for big data processing. This review presents a detailed overview of ML accelerated carbon neutrality research with a focus on energy management, screening of novel energy materials, and ML interatomic potentials (MLIPs), with illustrations of two selected MLIP algorithms: moment tensor potential (MTP) and neural equivariant interatomic potential (NequIP). We conclude by outlining the important role of ML in accelerating the achievement of carbon neutrality from global-scale energy management, unprecedented screening of advanced energy materials in massive chemical space, to the revolution of atomic-scale simulations of MLIPs, which has the bright prospect of applications.

AB - Carbon neutrality has been proposed as a solution for the current severe energy and climate crisis caused by the overuse of fossil fuels, and machine learning (ML) has exhibited excellent performance in accelerating related research owing to its powerful capacity for big data processing. This review presents a detailed overview of ML accelerated carbon neutrality research with a focus on energy management, screening of novel energy materials, and ML interatomic potentials (MLIPs), with illustrations of two selected MLIP algorithms: moment tensor potential (MTP) and neural equivariant interatomic potential (NequIP). We conclude by outlining the important role of ML in accelerating the achievement of carbon neutrality from global-scale energy management, unprecedented screening of advanced energy materials in massive chemical space, to the revolution of atomic-scale simulations of MLIPs, which has the bright prospect of applications.

KW - big data

KW - carbon neutrality

KW - interatomic potentials

KW - machine learning

KW - molecular dynamics

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SP - 2274

EP - 2296

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ER -

Machine learning accelerated carbon neutrality research using big data—from predictive models to interatomic potentials

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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