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Deep Residual Learning for Molecular Force Fields

22 October 2025, Version 4
Working Paper
This content is an early or alternative research output and has not been peer-reviewed by Cambridge University Press at the time of posting.

Abstract

Accurate interatomic interaction modeling via force fields is critical for biological studies and drug discovery, but balancing accuracy and generalizability remains challenging. We introduce ResFF (Residual Learning Force Field), a hybrid machine learning force field that employs deep residual learning to integrate physics-based learnable molecular mechanics covalent terms with residual corrections from a lightweight equivariant neural network. Through a three-stage joint optimization, the two components are trained in a complementary manner to achieve optimal performance. Benchmarks show ResFF outperforms classical and neural network force fields in generalization (mean absolute error (MAE): 1.16 kcal/mol on Gen2-Opt, 0.90 kcal/mol on DES370K), torsional profiles (MAE: 0.45/0.48 kcal/mol on TorsionNet-500 and Torison Scan), and intermolecular interactions (MAE: 0.32 kcal/mol on S66×8). It also enables precise energy minima reproduction and stable molecular dynamics of biological systems. ResFF merges physical constraints with neural expressiveness, offering a robust tool for accurate and efficient molecular simulation.

Keywords

Force Field
Neural Network
Generalizability

Supplementary materials

Title
Description
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Title
Supporting Information of ResFF
Description
Training details; metrics used in ResFF; examples of torsion prediction on the TorsionNet-500 dataset and Torsion Scan dataset; examples of dimer energy profiles on the S66×8 dataset; polyalanines folding dynamics; energy decomposition of ResFF; ablation experiments.
Actions
Title
Evaluation of Neural Network Force Fields in Molecular Simulation
Description
Additional comparisons of the ANI series force fields, AIMNet-2, SO3LR and ResFF on TorsionNet-500, Torsion Scan, s66x8 benchmarks and molecule dymamics simulation.
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Version History

Oct 22, 2025 Version 4

Version Notes

Additional comparisons of the ANI series force fields, AIMNet-2, SO3LR and ResFF on TorsionNet-500, Torsion Scan, s66x8 benchmarks and molecule dymamics simulation, are provided in a separate file.

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The content is available under CC BY NC ND 4.0 [opens in a new tab]

DOI

10.26434/chemrxiv-2025-003lg-v4
D O I: 10.26434/chemrxiv-2025-003lg-v4 [opens in a new tab]

Funding

National Natural Science Foundation of China
T2225002
National Natural Science Foundation of China
82273855
National Natural Science Foundation of China
82404513
National Key Research and Development Program of China
2022YFC3400504
National Key Research and Development Program of China
2023YFC2305904
SIMM-SHUTCM Traditional Chinese Medicine Innovation Joint Research Program
E2G805H
Shanghai Municipal Science and Technology Major Project

Author’s competing interest statement

The author(s) have declared they have no conflict of interest with regard to this content

Ethics

The author(s) declare that they have sought and gained approval from the relevant ethics committee/IRB for this research and its publication.

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