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When do short-range atomistic machine-learning models fall short?

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Atomistic machine-learning models struggle with long-range interactions, impacting cluster and vapor properties. Local models suffice for condensed liquid phases but require explicit long-range terms for broader accuracy.

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Area of Science:

  • Computational chemistry
  • Materials science
  • Machine learning

Background:

  • Atomistic machine-learning models are increasingly used in molecular simulations.
  • These models excel at learning complex local interactions but often lack explicit long-range interaction descriptions.
  • Understanding the necessity and impact of long-range interactions is crucial for model development.

Purpose of the Study:

  • To investigate the role of long-range interactions in atomistic machine-learning models.
  • To benchmark model performance across different property types (fitting accuracy, cluster properties, bulk thermodynamics).
  • To identify the limitations of short-range machine-learning models.

Main Methods:

  • Utilized a flexible Extended Simple Point Charge (SPC/E) water model as a benchmark system.
  • Analyzed fitting accuracy, isolated cluster properties, and bulk thermodynamic properties.
  • Compared performance of models with and without explicit long-range interaction descriptions.

Main Results:

  • Local machine-learning representations are adequate for predicting condensed liquid phase properties.
  • Short-range models demonstrate limitations in accurately representing cluster and vapor phase properties.
  • The inclusion of long-range interactions significantly improves the prediction of these properties.

Conclusions:

  • Explicit long-range interactions are essential for accurately modeling cluster and vapor phase properties in atomistic machine-learning models.
  • Local machine-learning models have specific regimes where their accuracy is limited.
  • This study provides insights into the necessary components for robust machine-learning models in molecular simulations.