TY - JOUR
T1 - Deep learning model to predict complex stress and strain fields in hierarchical composites
AU - Yang, Zhenze
AU - Yu, Chi Hua
AU - Buehler, Markus J.
N1 - Publisher Copyright:
Copyright © 2021 The Authors, some rights reserved.
PY - 2021/4/9
Y1 - 2021/4/9
N2 - Materials-by-design is a paradigm to develop previously unknown high-performance materials. However, finding materials with superior properties is often computationally or experimentally intractable because of the astronomical number of combinations in design space. Here we report an AI-based approach, implemented in a game theory-based conditional generative adversarial neural network (cGAN), to bridge the gap between a material's microstructure-the design space-and physical performance. Our end-to-end deep learning model predicts physical fields like stress or strain directly from the material microstructure geometry, and reaches an astonishing accuracy not only for predicted field data but also for derivative material property predictions. Furthermore, the proposed approach offers extensibility by predicting complex materials behavior regardless of component shapes, boundary conditions, and geometrical hierarchy, providing perspectives of performing physical modeling and simulations. The method vastly improves the efficiency of evaluating physical properties of hierarchical materials directly from the geometry of its structural makeup.
AB - Materials-by-design is a paradigm to develop previously unknown high-performance materials. However, finding materials with superior properties is often computationally or experimentally intractable because of the astronomical number of combinations in design space. Here we report an AI-based approach, implemented in a game theory-based conditional generative adversarial neural network (cGAN), to bridge the gap between a material's microstructure-the design space-and physical performance. Our end-to-end deep learning model predicts physical fields like stress or strain directly from the material microstructure geometry, and reaches an astonishing accuracy not only for predicted field data but also for derivative material property predictions. Furthermore, the proposed approach offers extensibility by predicting complex materials behavior regardless of component shapes, boundary conditions, and geometrical hierarchy, providing perspectives of performing physical modeling and simulations. The method vastly improves the efficiency of evaluating physical properties of hierarchical materials directly from the geometry of its structural makeup.
UR - http://www.scopus.com/inward/record.url?scp=85104209636&partnerID=8YFLogxK
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U2 - 10.1126/SCIADV.ABD7416
DO - 10.1126/SCIADV.ABD7416
M3 - Article
C2 - 33837076
AN - SCOPUS:85104209636
SN - 2375-2548
VL - 7
JO - Science Advances
JF - Science Advances
IS - 15
M1 - eabd7416
ER -