Fast atomic structure optimization with on-the-fly sparse Gaussian process potentials

Amir Hajibabaei; Muhammad Umer; Rohit Anand; Miran Ha; Kwang S. Kim

doi:10.1088/1361-648X/ac76ff

Fast atomic structure optimization with on-the-fly sparse Gaussian process potentials

Amir Hajibabaei
, Muhammad Umer
, Rohit Anand
, Miran Ha
, Kwang S. Kim

Ulsan National Institute of Science and Technology

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

Abstract

We apply on-the-fly machine learning potentials (MLPs) using the sparse Gaussian process regression (SGPR) algorithm for fast optimization of atomic structures. Great acceleration is achieved even in the context of a single local optimization. Although for finding the exact local minimum, due to limited accuracy of MLPs, switching to another algorithm may be needed. For random gold clusters, the forces are reduced to ~0.1 eV -1 within less than ten first-principles (FP) calculations. Because of highly transferable MLPs, this algorithm is specially suitable for global optimization methods such as random or evolutionary structure searching or basin hopping. This is demonstrated by sequential optimization of random gold clusters for which, after only a few optimizations, FP calculations were rarely needed.

Original language	English
Article number	344007
Journal	Journal of Physics Condensed Matter
Volume	34
Issue number	34
DOIs	https://doi.org/10.1088/1361-648X/ac76ff
Publication status	Published - 24 Aug 2022
Externally published	Yes

Keywords

machine learning potentials
sparse Gaussian process potentials
structure optimization

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10.1088/1361-648X/ac76ff

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title = "Fast atomic structure optimization with on-the-fly sparse Gaussian process potentials",

abstract = "We apply on-the-fly machine learning potentials (MLPs) using the sparse Gaussian process regression (SGPR) algorithm for fast optimization of atomic structures. Great acceleration is achieved even in the context of a single local optimization. Although for finding the exact local minimum, due to limited accuracy of MLPs, switching to another algorithm may be needed. For random gold clusters, the forces are reduced to \textasciitilde{}0.1 eV -1 within less than ten first-principles (FP) calculations. Because of highly transferable MLPs, this algorithm is specially suitable for global optimization methods such as random or evolutionary structure searching or basin hopping. This is demonstrated by sequential optimization of random gold clusters for which, after only a few optimizations, FP calculations were rarely needed.",

keywords = "machine learning potentials, sparse Gaussian process potentials, structure optimization",

author = "Amir Hajibabaei and Muhammad Umer and Rohit Anand and Miran Ha and Kim, \{Kwang S.\}",

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AU - Hajibabaei, Amir

AU - Umer, Muhammad

AU - Anand, Rohit

AU - Ha, Miran

AU - Kim, Kwang S.

PY - 2022/8/24

Y1 - 2022/8/24

N2 - We apply on-the-fly machine learning potentials (MLPs) using the sparse Gaussian process regression (SGPR) algorithm for fast optimization of atomic structures. Great acceleration is achieved even in the context of a single local optimization. Although for finding the exact local minimum, due to limited accuracy of MLPs, switching to another algorithm may be needed. For random gold clusters, the forces are reduced to ~0.1 eV -1 within less than ten first-principles (FP) calculations. Because of highly transferable MLPs, this algorithm is specially suitable for global optimization methods such as random or evolutionary structure searching or basin hopping. This is demonstrated by sequential optimization of random gold clusters for which, after only a few optimizations, FP calculations were rarely needed.

AB - We apply on-the-fly machine learning potentials (MLPs) using the sparse Gaussian process regression (SGPR) algorithm for fast optimization of atomic structures. Great acceleration is achieved even in the context of a single local optimization. Although for finding the exact local minimum, due to limited accuracy of MLPs, switching to another algorithm may be needed. For random gold clusters, the forces are reduced to ~0.1 eV -1 within less than ten first-principles (FP) calculations. Because of highly transferable MLPs, this algorithm is specially suitable for global optimization methods such as random or evolutionary structure searching or basin hopping. This is demonstrated by sequential optimization of random gold clusters for which, after only a few optimizations, FP calculations were rarely needed.

KW - machine learning potentials

KW - sparse Gaussian process potentials

KW - structure optimization

UR - https://www.scopus.com/pages/publications/85133576731

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DO - 10.1088/1361-648X/ac76ff

M3 - Article

AN - SCOPUS:85133576731

SN - 0953-8984

VL - 34

JO - Journal of Physics Condensed Matter

JF - Journal of Physics Condensed Matter

IS - 34

M1 - 344007

ER -

Fast atomic structure optimization with on-the-fly sparse Gaussian process potentials

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