Neuroevolution machine learning potentials: Combining high accuracy and low cost in atomistic simulations and application to heat transport

被引:250
作者
Fan, Zheyong [1 ,2 ]
Zeng, Zezhu [3 ]
Zhang, Cunzhi [4 ]
Wang, Yanzhou [2 ,5 ]
Song, Keke [5 ]
Dong, Haikuan [1 ,2 ,6 ]
Chen, Yue [3 ]
Nissila, Tapio Ala [2 ,7 ]
机构
[1] Bohai Univ, Coll Phys Sci & Technol, Jinzhou 121013, Peoples R China
[2] Aalto Univ, QTF Ctr Excellence, Dept Appl Phys, MSP Grp, FI-00076 Espoo, Finland
[3] Univ Hong Kong, Dept Mech Engn, Pokfulam Rd, Hong Kong, Peoples R China
[4] Univ Chicago, Pritzker Sch Mol Engn, Chicago, IL 60637 USA
[5] Univ Sci & Technol Beijing, Dept Phys, Beijing Adv Innovat Ctr Mat Genome Engn, Beijing 100083, Peoples R China
[6] Univ Sci & Technol Beijing, Corros & Protect Centel, Beijing Adv Innovat Ctr Mat Genome Engn, Beijing 100083, Peoples R China
[7] Loughborough Univ, Dept Math Sci, Interdisciplinary Ctr Math Modelling, Loughborough LE11 3TU, Leics, England
来源
PHYSICAL REVIEW B | 2021年 / 104卷 / 10期
基金
中国国家自然科学基金; 芬兰科学院;
关键词
MOLECULAR-DYNAMICS SIMULATIONS; THERMAL-CONDUCTIVITY;
D O I
10.1103/PhysRevB.104.104309
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
We develop a neuroevolution-potential (NEP) framework for generating neural network-based machine-learning potentials. They are trained using an evolutionary strategy for performing large-scale molecular dynamics (MD) simulations. A descriptor of the atomic environment is constructed based on Chebyshev and Legendre polynomials. The method is implemented in graphic processing units within the open-source GPUMD package, which can attain a computational speed over 10(7) atom-step per second using one Nvidia Tesla V100. Furthermore, per-atom heat current is available in NEP, which paves the way for efficient and accurate MD simulations of heat transport in materials with strong phonon anharmonicity or spatial disorder, which usually cannot be accurately treated either with traditional empirical potentials or with perturbative methods.
引用
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页数:15
相关论文
共 95 条
[1]   Efficient and accurate machine-learning interpolation of atomic energies in compositions with many species [J].
Artrith, Nongnuch ;
Urban, Alexander ;
Ceder, Gerbrand .
PHYSICAL REVIEW B, 2017, 96 (01)
[2]   Machine-learning-based interatomic potential for phonon transport in perfect crystalline Si and crystalline Si with vacancies [J].
Banaei, Hasan ;
Guo, Ruiqiang ;
Hashemi, Amirreza ;
Lee, Sangyeop .
PHYSICAL REVIEW MATERIALS, 2019, 3 (07)
[3]   Machine Learning a General-Purpose Interatomic Potential for Silicon [J].
Bartok, Albert P. ;
Kermode, James ;
Bernstein, Noam ;
Csanyi, Gabor .
PHYSICAL REVIEW X, 2018, 8 (04)
[4]   On representing chemical environments [J].
Bartok, Albert P. ;
Kondor, Risi ;
Csanyi, Gabor .
PHYSICAL REVIEW B, 2013, 87 (18)
[5]   Gaussian Approximation Potentials: The Accuracy of Quantum Mechanics, without the Electrons [J].
Bartok, Albert P. ;
Payne, Mike C. ;
Kondor, Risi ;
Csanyi, Gabor .
PHYSICAL REVIEW LETTERS, 2010, 104 (13)
[6]   Generalized neural-network representation of high-dimensional potential-energy surfaces [J].
Behler, Joerg ;
Parrinello, Michele .
PHYSICAL REVIEW LETTERS, 2007, 98 (14)
[7]   Perspective: Machine learning potentials for atomistic simulations [J].
Behler, Joerg .
JOURNAL OF CHEMICAL PHYSICS, 2016, 145 (17)
[8]   Atom-centered symmetry functions for constructing high-dimensional neural network potentials [J].
Behler, Joerg .
JOURNAL OF CHEMICAL PHYSICS, 2011, 134 (07)
[9]   PROJECTOR AUGMENTED-WAVE METHOD [J].
BLOCHL, PE .
PHYSICAL REVIEW B, 1994, 50 (24) :17953-17979
[10]   Heat Flux for Many-Body Interactions: Corrections to LAMMPS [J].
Boone, Paul ;
Babaei, Hasan ;
Wilmer, Christopher E. .
JOURNAL OF CHEMICAL THEORY AND COMPUTATION, 2019, 15 (10) :5579-5587
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