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Improving molecular force fields across configurational space by combining supervised and unsupervised machine

Gregory Fonseca1, Igor Poltavsky1, Valentin Vassilev-Galindo1

  • 1Department of Physics and Materials Science, University of Luxembourg, L-1511 Luxembourg, Luxembourg.

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This summary is machine-generated.

This study introduces a novel machine learning approach to improve molecular simulations. By strategically selecting training data, it enhances the accuracy and stability of machine learning force fields (MLFFs) for diverse molecular configurations.

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Area of Science:

  • Computational Chemistry
  • Materials Science
  • Machine Learning

Background:

  • Machine Learning Force Fields (MLFFs) are crucial for molecular simulations.
  • Current MLFFs often suffer from biased training data, limiting their accuracy to common configurations.
  • This bias restricts the applicability of MLFF models in predictive molecular simulations.

Purpose of the Study:

  • To develop a novel method for selecting training data to improve MLFF performance.
  • To overcome the limitations of inhomogeneously distributed datasets in configurational space (CS).
  • To enhance the accuracy and applicability of MLFFs for diverse molecular configurations, including non-equilibrium geometries.

Main Methods:

  • Combined unsupervised and supervised machine learning (ML) methods.
  • Clustering of configurational space (CS) into geometrically and energetically similar subregions.
  • Iterative testing of MLFF performance on subregions and targeted inclusion of data from inaccurate regions into the training set.

Main Results:

  • Achieved up to a twofold decrease in root mean squared errors for force predictions on non-equilibrium geometries.
  • Demonstrated superior stability of ML models compared to default training approaches.
  • Validated the approach across different ML methods, including kernel-based models (sGDML, GAP/SOAP) and deep neural networks (SchNet).

Conclusions:

  • The proposed data selection strategy effectively mitigates bias towards common configurations.
  • This method significantly widens the applicability range of MLFFs for molecular simulations.
  • Enables reliable studies of processes involving highly out-of-equilibrium molecular configurations.