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Main Authors: Blanco-González, Alexandre, Schulze, Thea K, Rovers, Evianne, Greener, Joe G
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.16770
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author Blanco-González, Alexandre
Schulze, Thea K
Rovers, Evianne
Greener, Joe G
author_facet Blanco-González, Alexandre
Schulze, Thea K
Rovers, Evianne
Greener, Joe G
contents Force fields for molecular dynamics are usually developed manually, limiting their transferability and making systematic exploration of functional forms challenging. We developed a graph neural network that assigns all force field parameters for diverse molecules using continuous atom typing. The freely-available model, called Garnet, was trained on quantum mechanical, condensed phase and protein nuclear magnetic resonance data without the use of existing parameters. The resulting force field shows comparable performance to current force fields on small molecules, folded proteins, protein complexes and disordered proteins. It shows similar results to popular approaches for relative binding free energy predictions across a range of targets. Assessing different functional forms shows that the double exponential potential is a flexible and accurate alternative to the Lennard-Jones potential. Garnet provides a platform for automated, reproducible force field discovery that brings the benefits of machine learning to classical force fields.
format Preprint
id arxiv_https___arxiv_org_abs_2603_16770
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Training a force field for proteins and small molecules from scratch
Blanco-González, Alexandre
Schulze, Thea K
Rovers, Evianne
Greener, Joe G
Biomolecules
Force fields for molecular dynamics are usually developed manually, limiting their transferability and making systematic exploration of functional forms challenging. We developed a graph neural network that assigns all force field parameters for diverse molecules using continuous atom typing. The freely-available model, called Garnet, was trained on quantum mechanical, condensed phase and protein nuclear magnetic resonance data without the use of existing parameters. The resulting force field shows comparable performance to current force fields on small molecules, folded proteins, protein complexes and disordered proteins. It shows similar results to popular approaches for relative binding free energy predictions across a range of targets. Assessing different functional forms shows that the double exponential potential is a flexible and accurate alternative to the Lennard-Jones potential. Garnet provides a platform for automated, reproducible force field discovery that brings the benefits of machine learning to classical force fields.
title Training a force field for proteins and small molecules from scratch
topic Biomolecules
url https://arxiv.org/abs/2603.16770