PARC: Physics-Aware Recurrent Convolutional Neural Networks to Assimilate Meso-scale Reactive Mechanics of Energetic Materials

The thermo-mechanical response of shock-initiated energetic materials (EM) is highly influenced by their microstructures, presenting an opportunity to engineer EM microstructure in a "materials-by-design" framework. However, the current design practice is limited, as a large ensemble of si...

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Veröffentlicht in:	arXiv.org 2023-03
Hauptverfasser:	Nguyen, Phong C H, Yen-Thi Nguyen, Choi, Joseph B, Seshadri, Pradeep K, Udaykumar, H S, Baek, Stephen
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer Science - Learning Computer simulation Computing time Crystal structure Detonation Direct numerical simulation Energetic materials Mathematical models Mesoscale phenomena Microstructure Neural networks Physics Physics - Materials Science Thermodynamics Thermomechanical properties
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creator	Nguyen, Phong C H Yen-Thi Nguyen Choi, Joseph B Seshadri, Pradeep K Udaykumar, H S Baek, Stephen
description	The thermo-mechanical response of shock-initiated energetic materials (EM) is highly influenced by their microstructures, presenting an opportunity to engineer EM microstructure in a "materials-by-design" framework. However, the current design practice is limited, as a large ensemble of simulations is required to construct the complex EM structure-property-performance linkages. We present the Physics-Aware Recurrent Convolutional (PARC) Neural Network, a deep-learning algorithm capable of learning the mesoscale thermo-mechanics of EM from a modest number of high-resolution direct numerical simulations (DNS). Validation results demonstrated that PARC could predict the themo-mechanical response of shocked EM with a comparable accuracy to DNS but with notably less computation time. The physics awareness of PARC enhances its modeling capabilities and generalizability, especially when challenged in unseen prediction scenarios. We also demonstrate that visualizing the artificial neurons at PARC can shed light on important aspects of EM thermos-mechanics and provide an additional lens for conceptualizing EM.
doi_str_mv	10.48550/arxiv.2204.07234
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subjects	Computer Science - Learning Computer simulation Computing time Crystal structure Detonation Direct numerical simulation Energetic materials Mathematical models Mesoscale phenomena Microstructure Neural networks Physics Physics - Materials Science Thermodynamics Thermomechanical properties
title	PARC: Physics-Aware Recurrent Convolutional Neural Networks to Assimilate Meso-scale Reactive Mechanics of Energetic Materials
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