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Coarse-Grained Force Field Calibration Based on Multiobjective Bayesian Optimization to Simulate Water Diffusion in Poly-ε-caprolactone

Jesse M. Sestito, Mary L. Thatcher, Leshi Shu, Tequila A. L. Harris, Yan Wang

2020The Journal of Physical Chemistry A17 citationsDOI

Abstract

Molecular dynamics at the atomistic scale is increasingly being used to predict material properties and speed up the material design and development process. However, the accuracy of molecular dynamics predictions is sensitively dependent on the force fields. In the traditional force field calibration process, a specific property, predicted by the model, is compared with the experimental observation and the force field parameters are adjusted to minimize the difference. This leads to the issue that the calibrated force fields are not generic and robust enough to predict different properties. Here, a new calibration method based on multiobjective Bayesian optimization is developed to speed up the development of molecular dynamics force fields that are capable of predicting multiple properties accurately. This is achieved by reducing the number of simulation runs to generate the Pareto front with an efficient sequential sampling strategy. The methodology is demonstrated by generating a new coarse-grained force field for polycaprolactone, where the force field can predict the mechanical properties and water diffusion in the polymer.

Topics & Concepts

Force field (fiction)CalibrationMolecular dynamicsField (mathematics)Computer scienceMulti-objective optimizationSampling (signal processing)Process (computing)Materials scienceBiological systemStatistical physicsMathematical optimizationMathematicsPhysicsArtificial intelligenceMachine learningStatisticsFilter (signal processing)BiologyComputer visionPure mathematicsQuantum mechanicsOperating systemRheology and Fluid Dynamics StudiesPolymer crystallization and propertiesInjection Molding Process and Properties