基于商数复合(QC)的二维包晶设计机器学习

Chuan-Shen Hu, Rishikanta Mayengbam, Kelin Xia, Tze Chien Sum
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摘要

二维(2D)卤化物层状过氧化物具有非凡的稳定性和特殊的光电特性,为光电技术的革命带来了巨大的希望。目前,不充分的表征极大地阻碍了二维过氧化物的设计和发现。在这种情况下,我们引入了一种新颖的计算拓扑框架,称为商复合体(QC),作为材料表征的基础。我们基于 QC 的特征与学习模型无缝集成,促进了二维包晶设计的发展。该框架的核心是商复合物描述符(QCD),它代表了从材料单胞和周期边界条件衍生出的简单复合物的商变化。与之前的材料表征不同,这种方法同时编码了高阶相互作用和周期性信息。基于成熟的太阳能新材料(NMSE)数据库,我们的基于 QC 的机器学习模型与所有现有的同类模型相比表现出更优越的性能。这强调了周期性信息在预测材料功能方面的重要作用,同时也展示了基于 QC 的模型在表征材料结构属性方面的显著效率。
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Quotient complex (QC)-based machine learning for 2D perovskite design
With remarkable stability and exceptional optoelectronic properties, two-dimensional (2D) halide layered perovskites hold immense promise for revolutionizing photovoltaic technology. Presently, inadequate representations have substantially impeded the design and discovery of 2D perovskites. In this context, we introduce a novel computational topology framework termed the quotient complex (QC), which serves as the foundation for the material representation. Our QC-based features are seamlessly integrated with learning models for the advancement of 2D perovskite design. At the heart of this framework lies the quotient complex descriptors (QCDs), representing a quotient variation of simplicial complexes derived from materials unit cell and periodic boundary conditions. Differing from prior material representations, this approach encodes higher-order interactions and periodicity information simultaneously. Based on the well-established New Materials for Solar Energetics (NMSE) databank, our QC-based machine learning models exhibit superior performance against all existing counterparts. This underscores the paramount role of periodicity information in predicting material functionality, while also showcasing the remarkable efficiency of the QC-based model in characterizing materials structural attributes.
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