Molecular dynamics simulation of the transformation of Fe-Co alloy by machine learning force field based on atomic cluster expansion

Yongle Li; Feng Xu; Long Hou; Luchao Sun; Haijun Su; Xi Li; Wei Ren

doi:10.1016/j.cplett.2023.140646

Molecular dynamics simulation of the transformation of Fe-Co alloy by machine learning force field based on atomic cluster expansion

Yongle Li, Feng Xu, Long Hou, Luchao Sun, Haijun Su, Xi Li, Wei Ren

School of Materials Sience and Engineering

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

3 Scopus citations

Abstract

The force field describing the calculated interaction between atoms or molecules is the key to the accuracy of many molecular dynamics (MD) simulation results. Compared with traditional or semi-empirical force fields, machine learning force fields have the advantages of faster speed and higher precision. We have employed the method of atomic cluster expansion (ACE) combined with first-principles density functional theory (DFT) calculations for machine learning, and successfully obtained the force field of the binary Fe-Co alloy. Molecular dynamics simulations of Fe-Co alloy carried out using this ACE force field predicted the correct phase transition range of Fe-Co alloy.

Original language	English
Article number	140646
Journal	Chemical Physics Letters
Volume	826
DOIs	https://doi.org/10.1016/j.cplett.2023.140646
State	Published - Sep 2023

Keywords

Atomic cluster expansion
Density functional theory
Fe-Co Alloy
Force field
Molecular dynamics
Phase transition

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10.1016/j.cplett.2023.140646

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title = "Molecular dynamics simulation of the transformation of Fe-Co alloy by machine learning force field based on atomic cluster expansion",

abstract = "The force field describing the calculated interaction between atoms or molecules is the key to the accuracy of many molecular dynamics (MD) simulation results. Compared with traditional or semi-empirical force fields, machine learning force fields have the advantages of faster speed and higher precision. We have employed the method of atomic cluster expansion (ACE) combined with first-principles density functional theory (DFT) calculations for machine learning, and successfully obtained the force field of the binary Fe-Co alloy. Molecular dynamics simulations of Fe-Co alloy carried out using this ACE force field predicted the correct phase transition range of Fe-Co alloy.",

keywords = "Atomic cluster expansion, Density functional theory, Fe-Co Alloy, Force field, Molecular dynamics, Phase transition",

author = "Yongle Li and Feng Xu and Long Hou and Luchao Sun and Haijun Su and Xi Li and Wei Ren",

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year = "2023",

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doi = "10.1016/j.cplett.2023.140646",

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T1 - Molecular dynamics simulation of the transformation of Fe-Co alloy by machine learning force field based on atomic cluster expansion

AU - Li, Yongle

AU - Xu, Feng

AU - Hou, Long

AU - Sun, Luchao

AU - Su, Haijun

AU - Li, Xi

AU - Ren, Wei

PY - 2023/9

Y1 - 2023/9

N2 - The force field describing the calculated interaction between atoms or molecules is the key to the accuracy of many molecular dynamics (MD) simulation results. Compared with traditional or semi-empirical force fields, machine learning force fields have the advantages of faster speed and higher precision. We have employed the method of atomic cluster expansion (ACE) combined with first-principles density functional theory (DFT) calculations for machine learning, and successfully obtained the force field of the binary Fe-Co alloy. Molecular dynamics simulations of Fe-Co alloy carried out using this ACE force field predicted the correct phase transition range of Fe-Co alloy.

AB - The force field describing the calculated interaction between atoms or molecules is the key to the accuracy of many molecular dynamics (MD) simulation results. Compared with traditional or semi-empirical force fields, machine learning force fields have the advantages of faster speed and higher precision. We have employed the method of atomic cluster expansion (ACE) combined with first-principles density functional theory (DFT) calculations for machine learning, and successfully obtained the force field of the binary Fe-Co alloy. Molecular dynamics simulations of Fe-Co alloy carried out using this ACE force field predicted the correct phase transition range of Fe-Co alloy.

KW - Atomic cluster expansion

KW - Density functional theory

KW - Fe-Co Alloy

KW - Force field

KW - Molecular dynamics

KW - Phase transition

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DO - 10.1016/j.cplett.2023.140646

M3 - 文章

AN - SCOPUS:85161636883

SN - 0009-2614

VL - 826

JO - Chemical Physics Letters

JF - Chemical Physics Letters

M1 - 140646

ER -

Molecular dynamics simulation of the transformation of Fe-Co alloy by machine learning force field based on atomic cluster expansion

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Keywords

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