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Main Authors: Kulaev, Kirill, Ryabov, Alexander, Medvedev, Michael, Burnaev, Evgeny, Vanovskiy, Vladimir
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.12149
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author Kulaev, Kirill
Ryabov, Alexander
Medvedev, Michael
Burnaev, Evgeny
Vanovskiy, Vladimir
author_facet Kulaev, Kirill
Ryabov, Alexander
Medvedev, Michael
Burnaev, Evgeny
Vanovskiy, Vladimir
contents Density functional theory (DFT) is probably the most promising approach for quantum chemistry calculations considering its good balance between calculations precision and speed. In recent years, several neural network-based functionals have been developed for exchange-correlation energy approximation in DFT, DM21 developed by Google Deepmind being the most notable between them. This study focuses on evaluating the efficiency of DM21 functional in predicting molecular geometries, with a focus on the influence of oscillatory behavior in neural network exchange-correlation functionals. We implemented geometry optimization in PySCF for the DM21 functional in geometry optimization problem, compared its performance with traditional functionals, and tested it on various benchmarks. Our findings reveal both the potential and the current challenges of using neural network functionals for geometry optimization in DFT. We propose a solution extending the practical applicability of such functionals and allowing to model new substances with their help.
format Preprint
id arxiv_https___arxiv_org_abs_2501_12149
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle On the practical applicability of modern DFT functionals for chemical computations. Case study of DM21 applicability for geometry optimization
Kulaev, Kirill
Ryabov, Alexander
Medvedev, Michael
Burnaev, Evgeny
Vanovskiy, Vladimir
Computational Physics
Materials Science
Artificial Intelligence
Density functional theory (DFT) is probably the most promising approach for quantum chemistry calculations considering its good balance between calculations precision and speed. In recent years, several neural network-based functionals have been developed for exchange-correlation energy approximation in DFT, DM21 developed by Google Deepmind being the most notable between them. This study focuses on evaluating the efficiency of DM21 functional in predicting molecular geometries, with a focus on the influence of oscillatory behavior in neural network exchange-correlation functionals. We implemented geometry optimization in PySCF for the DM21 functional in geometry optimization problem, compared its performance with traditional functionals, and tested it on various benchmarks. Our findings reveal both the potential and the current challenges of using neural network functionals for geometry optimization in DFT. We propose a solution extending the practical applicability of such functionals and allowing to model new substances with their help.
title On the practical applicability of modern DFT functionals for chemical computations. Case study of DM21 applicability for geometry optimization
topic Computational Physics
Materials Science
Artificial Intelligence
url https://arxiv.org/abs/2501.12149