Saved in:
Bibliographic Details
Main Authors: Immel, David, Drautz, Ralf, Sutmann, Godehard
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.03002
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912339734822912
author Immel, David
Drautz, Ralf
Sutmann, Godehard
author_facet Immel, David
Drautz, Ralf
Sutmann, Godehard
contents Large-scale atomistic simulations rely on interatomic potentials providing an efficient representation of atomic energies and forces. Modern machine-learning (ML) potentials provide the most precise representation compared to electronic structure calculations while traditional potentials provide a less precise, but computationally much faster representation and thus allow simulations of larger systems. We present a method to combine a traditional and a ML potential to a multi-resolution description, leading to an adaptive-precision potential with an optimum of performance and precision in large complex atomistic systems. The required precision is determined per atom by a local structure analysis and updated automatically during simulation. We use copper as demonstrator material with an embedded atom model as classical force field and an atomic cluster expansion (ACE) as ML potential, but in principle a broader class of potential combinations can be coupled by this method. The approach is developed for the molecular-dynamics simulator LAMMPS and includes a load-balancer to prevent problems due to the atom dependent force-calculation times, which makes it suitable for large-scale atomistic simulations. The developed adaptive-precision copper potential represents the ACE-forces and -energies with a precision of 10 meV/Å and 0 meV for the precisely calculated atoms in a nanoindentation of 4 million atoms calculated for 100 ps and shows a speedup of 11.3 compared with a full ACE simulation.
format Preprint
id arxiv_https___arxiv_org_abs_2411_03002
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Adaptive-precision potentials for large-scale atomistic simulations
Immel, David
Drautz, Ralf
Sutmann, Godehard
Computational Physics
Large-scale atomistic simulations rely on interatomic potentials providing an efficient representation of atomic energies and forces. Modern machine-learning (ML) potentials provide the most precise representation compared to electronic structure calculations while traditional potentials provide a less precise, but computationally much faster representation and thus allow simulations of larger systems. We present a method to combine a traditional and a ML potential to a multi-resolution description, leading to an adaptive-precision potential with an optimum of performance and precision in large complex atomistic systems. The required precision is determined per atom by a local structure analysis and updated automatically during simulation. We use copper as demonstrator material with an embedded atom model as classical force field and an atomic cluster expansion (ACE) as ML potential, but in principle a broader class of potential combinations can be coupled by this method. The approach is developed for the molecular-dynamics simulator LAMMPS and includes a load-balancer to prevent problems due to the atom dependent force-calculation times, which makes it suitable for large-scale atomistic simulations. The developed adaptive-precision copper potential represents the ACE-forces and -energies with a precision of 10 meV/Å and 0 meV for the precisely calculated atoms in a nanoindentation of 4 million atoms calculated for 100 ps and shows a speedup of 11.3 compared with a full ACE simulation.
title Adaptive-precision potentials for large-scale atomistic simulations
topic Computational Physics
url https://arxiv.org/abs/2411.03002