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Deep learning modeling strategy for material science: from natural materials to metamaterials

Wenwen Li, Pu Chen, Bo Xiong, Guandong Liu, Shuliang Dou, Yaohui Zhan, Zhiyuan Zhu, Tao Chu, Yao Li, Wei Ma

2022Journal of Physics Materials26 citationsDOIOpen Access PDF

Abstract

Abstract Computational modeling is a crucial approach in material-related research for discovering new materials with superior properties. However, the high design flexibility in materials, especially in the realm of metamaterials where the sub-wavelength structure provides an additional degree of freedom in design, poses a formidable computational cost in various real-world applications. With the advent of big data, deep learning (DL) brings revolutionary breakthroughs in many conventional machine learning and pattern recognition tasks such as image classification. The accompanied data-driven modeling paradigm also provides transformative methodology shift in materials science, from trial-and-error routine to intelligent material discovery and analysis. This review systematically summarize the application of DL in material science, based on a model selection perspective for both natural materials and metamaterials. The review aims to uncover the logic behind data-model relation with emphasis on suitable data structures for different scenarios in the material study and the corresponding problem-solving DL model architectures.

Topics & Concepts

Computer scienceMetamaterialDeep learningTransformative learningArtificial intelligenceFlexibility (engineering)Big dataData scienceRelation (database)RealmComputational modelData miningMaterials sciencePolitical scienceOptoelectronicsLawPsychologyPedagogyMathematicsStatisticsMachine Learning in Materials ScienceX-ray Diffraction in CrystallographyElectron and X-Ray Spectroscopy Techniques