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Accelerating phase-field-based microstructure evolution predictions via surrogate models trained by machine learning methods

David Montes de Oca Zapiain, James A. Stewart, Rémi Dingreville

2021npj Computational Materials211 citationsDOIOpen Access PDF

Abstract

Abstract The phase-field method is a powerful and versatile computational approach for modeling the evolution of microstructures and associated properties for a wide variety of physical, chemical, and biological systems. However, existing high-fidelity phase-field models are inherently computationally expensive, requiring high-performance computing resources and sophisticated numerical integration schemes to achieve a useful degree of accuracy. In this paper, we present a computationally inexpensive, accurate, data-driven surrogate model that directly learns the microstructural evolution of targeted systems by combining phase-field and history-dependent machine-learning techniques. We integrate a statistically representative, low-dimensional description of the microstructure, obtained directly from phase-field simulations, with either a time-series multivariate adaptive regression splines autoregressive algorithm or a long short-term memory neural network. The neural-network-trained surrogate model shows the best performance and accurately predicts the nonlinear microstructure evolution of a two-phase mixture during spinodal decomposition in seconds, without the need for “on-the-fly” solutions of the phase-field equations of motion. We also show that the predictions from our machine-learned surrogate model can be fed directly as an input into a classical high-fidelity phase-field model in order to accelerate the high-fidelity phase-field simulations by leaping in time. Such machine-learned phase-field framework opens a promising path forward to use accelerated phase-field simulations for discovering, understanding, and predicting processing–microstructure–performance relationships.

Topics & Concepts

Field (mathematics)Computer sciencePhase field modelsArtificial intelligenceMachine learningPhase (matter)Spinodal decompositionSurrogate modelAutoregressive modelArtificial neural networkAlgorithmMathematicsOrganic chemistryChemistryPure mathematicsEconometricsSolidification and crystal growth phenomenaMachine Learning in Materials ScienceBlock Copolymer Self-Assembly
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