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Building Chemical Property Models for Energetic Materials from Small Datasets Using a Transfer Learning Approach

Joshua L. Lansford, Brian C. Barnes, Betsy M. Rice, Klavs F. Jensen

2022Journal of Chemical Information and Modeling41 citationsDOI

Abstract

For many experimentally measured chemical properties that cannot be directly computed from first-principles, the existing physics-based models do not extrapolate well to out-of-sample molecules, and experimental datasets themselves are too small for traditional machine learning (ML) approaches. To overcome these limitations, we apply a transfer learning approach, whereby we simultaneously train a multi-target regression model on a small number of molecules with experimentally measured values and a large number of molecules with related computed properties. We demonstrate this methodology on predicting the experimentally measured impact sensitivity of energetic crystals, finding that both characteristics of the computed dataset and model architecture are important to prediction accuracy of the small experimental dataset. Our directed-message passing neural network (D-MPNN) ML model using transfer learning outperforms direct-ML and physics-based models on a diverse test set, and the new methods described here are widely applicable to modeling many other structure-property relationships.

Topics & Concepts

Transfer of learningProperty (philosophy)Computer scienceArtificial neural networkMachine learningArtificial intelligenceSet (abstract data type)Sensitivity (control systems)Test setRegressionTransfer (computing)Biological systemData setProperty valueMathematicsStatisticsElectronic engineeringEpistemologyParallel computingProgramming languageLawPolitical scienceReal estateBiologyEngineeringPhilosophyEnergetic Materials and CombustionMachine Learning in Materials ScienceComputational Drug Discovery Methods
Building Chemical Property Models for Energetic Materials from Small Datasets Using a Transfer Learning Approach | Litcius