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Autori principali: Benedini, Giulio, Loew, Antoine, Hellstrom, Matti, Botti, Silvana, Marques, Miguel A. L.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.15614
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author Benedini, Giulio
Loew, Antoine
Hellstrom, Matti
Botti, Silvana
Marques, Miguel A. L.
author_facet Benedini, Giulio
Loew, Antoine
Hellstrom, Matti
Botti, Silvana
Marques, Miguel A. L.
contents We present a benchmark designed to evaluate the predictive capabilities of universal machine learning interatomic potentials across systems of varying dimensionality. Specifically, our benchmark tests zero- (molecules, atomic clusters, etc.), one- (nanowires, nanoribbons, nanotubes, etc.), two- (atomic layers and slabs) and three-dimensional (bulk materials) compounds. The benchmark reveals that while all tested models demonstrate excellent performance for three-dimensional systems, accuracy degrades progressively for lower-dimensional structures. The best performing models for geometry optimization are orbital version 2, equiformerV2, and the equivariant Smooth Energy Network, with the equivariant Smooth Energy Network also providing the most accurate energies. Our results indicate that the best models yield, on average, errors in the atomic positions in the range of 0.01-0.02 angstrom and errors in the energy below 10~meV/atom across all dimensionalities. These results demonstrate that state-of-the-art universal machine learning interatomic potentials have reached sufficient accuracy to serve as direct replacements for density functional theory calculations, at a small fraction of the computational cost, in simulations spanning the full range from isolated atoms to bulk solids. More significantly, the best performing models already enable efficient simulations of complex systems containing subsystems of mixed dimensionality, opening new possibilities for modeling realistic materials and interfaces.
format Preprint
id arxiv_https___arxiv_org_abs_2508_15614
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Universal Machine Learning Potential for Systems with Reduced Dimensionality
Benedini, Giulio
Loew, Antoine
Hellstrom, Matti
Botti, Silvana
Marques, Miguel A. L.
Materials Science
Computational Physics
We present a benchmark designed to evaluate the predictive capabilities of universal machine learning interatomic potentials across systems of varying dimensionality. Specifically, our benchmark tests zero- (molecules, atomic clusters, etc.), one- (nanowires, nanoribbons, nanotubes, etc.), two- (atomic layers and slabs) and three-dimensional (bulk materials) compounds. The benchmark reveals that while all tested models demonstrate excellent performance for three-dimensional systems, accuracy degrades progressively for lower-dimensional structures. The best performing models for geometry optimization are orbital version 2, equiformerV2, and the equivariant Smooth Energy Network, with the equivariant Smooth Energy Network also providing the most accurate energies. Our results indicate that the best models yield, on average, errors in the atomic positions in the range of 0.01-0.02 angstrom and errors in the energy below 10~meV/atom across all dimensionalities. These results demonstrate that state-of-the-art universal machine learning interatomic potentials have reached sufficient accuracy to serve as direct replacements for density functional theory calculations, at a small fraction of the computational cost, in simulations spanning the full range from isolated atoms to bulk solids. More significantly, the best performing models already enable efficient simulations of complex systems containing subsystems of mixed dimensionality, opening new possibilities for modeling realistic materials and interfaces.
title Universal Machine Learning Potential for Systems with Reduced Dimensionality
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2508.15614