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Auteurs principaux: Kurniawan, Yonatan, Petrie, Cody L., Transtrum, Mark K., Tadmor, Ellad B., Elliott, Ryan S., Karls, Daniel S., Wen, Mingjian
Format: Preprint
Publié: 2022
Sujets:
Accès en ligne:https://arxiv.org/abs/2206.00578
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author Kurniawan, Yonatan
Petrie, Cody L.
Transtrum, Mark K.
Tadmor, Ellad B.
Elliott, Ryan S.
Karls, Daniel S.
Wen, Mingjian
author_facet Kurniawan, Yonatan
Petrie, Cody L.
Transtrum, Mark K.
Tadmor, Ellad B.
Elliott, Ryan S.
Karls, Daniel S.
Wen, Mingjian
contents Atomistic simulations are an important tool in materials modeling. Interatomic potentials (IPs) are at the heart of such molecular models, and the accuracy of a model's predictions depends strongly on the choice of IP. Uncertainty quantification (UQ) is an emerging tool for assessing the reliability of atomistic simulations. The Open Knowledgebase of Interatomic Models (OpenKIM) is a cyberinfrastructure project whose goal is to collect and standardize the study of IPs to enable transparent, reproducible research. Part of the OpenKIM framework is the Python package, KIM-based Learning-Integrated Fitting Framework (KLIFF), that provides tools for fitting parameters in an IP to data. This paper introduces a UQ toolbox extension to KLIFF. We focus on two sources of uncertainty: variations in parameters and inadequacy of the functional form of the IP. Our implementation uses parallel-tempered Markov chain Monte Carlo (PTMCMC), adjusting the sampling temperature to estimate the uncertainty due to the functional form of the IP. We demonstrate on a Stillinger--Weber potential that makes predictions for the atomic energies and forces for silicon in a diamond configuration. Finally, we highlight some potential subtleties in applying and using these tools with recommendations for practitioners and IP developers.
format Preprint
id arxiv_https___arxiv_org_abs_2206_00578
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Extending OpenKIM with an Uncertainty Quantification Toolkit for Molecular Modeling
Kurniawan, Yonatan
Petrie, Cody L.
Transtrum, Mark K.
Tadmor, Ellad B.
Elliott, Ryan S.
Karls, Daniel S.
Wen, Mingjian
Computational Physics
Atomistic simulations are an important tool in materials modeling. Interatomic potentials (IPs) are at the heart of such molecular models, and the accuracy of a model's predictions depends strongly on the choice of IP. Uncertainty quantification (UQ) is an emerging tool for assessing the reliability of atomistic simulations. The Open Knowledgebase of Interatomic Models (OpenKIM) is a cyberinfrastructure project whose goal is to collect and standardize the study of IPs to enable transparent, reproducible research. Part of the OpenKIM framework is the Python package, KIM-based Learning-Integrated Fitting Framework (KLIFF), that provides tools for fitting parameters in an IP to data. This paper introduces a UQ toolbox extension to KLIFF. We focus on two sources of uncertainty: variations in parameters and inadequacy of the functional form of the IP. Our implementation uses parallel-tempered Markov chain Monte Carlo (PTMCMC), adjusting the sampling temperature to estimate the uncertainty due to the functional form of the IP. We demonstrate on a Stillinger--Weber potential that makes predictions for the atomic energies and forces for silicon in a diamond configuration. Finally, we highlight some potential subtleties in applying and using these tools with recommendations for practitioners and IP developers.
title Extending OpenKIM with an Uncertainty Quantification Toolkit for Molecular Modeling
topic Computational Physics
url https://arxiv.org/abs/2206.00578