从晶体结构中学习原子

Andrij VasylenkoDepartment of Chemistry, University of Liverpool, Crown Street, United Kingdom, Dmytro AntypovDepartment of Chemistry, University of Liverpool, Crown Street, United Kingdom, Sven ScheweDepartment of Computer Science, University of Liverpool, Ashton Building, United Kingdom, Luke M. DanielsDepartment of Chemistry, University of Liverpool, Crown Street, United Kingdom, John B. ClaridgeDepartment of Chemistry, University of Liverpool, Crown Street, United Kingdom, Matthew S. DyerDepartment of Chemistry, University of Liverpool, Crown Street, United Kingdom, Matthew J. RosseinskyDepartment of Chemistry, University of Liverpool, Crown Street, United Kingdom
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引用次数: 0

摘要

利用机器学习、ML 和历史数据对材料进行计算建模已成为材料研究不可或缺的一部分。计算建模的效率受到描述成分、结构和化学元素的数值描述方法选择的强烈影响。在本研究中,我们引入了局部环境诱导原子特征(Local Environment-induced Atomic Features,LEAFs),它将晶体结构中原子的统计优选局部配位几何信息纳入化学元素描述符中,从而无需了解晶体结构即可将材料完全作为成分建模。在晶体结构中,每个原子位点都可以通过与常见局部结构图案的相似性来描述;通过汇总无机材料经实验验证的晶体结构中的这些相似性特征,LEAF 形成了一套化学元素和成分的描述符。LEAF 与局部配位几何的直接联系使我们能够分析 ML 模型的性质预测,将成分与基本的结构-性质关系联系起来。我们展示了 LEAFs 在以结构为基础的成分性质预测、以结构为基础的化学空间映射以及优先考虑元素置换等方面的多功能性。这些结果表明,这项工作中开发的化学元素和成分的结构信息描述可以有效地指导发现新材料的合成工作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Learning Atoms from Crystal Structure
Computational modelling of materials using machine learning, ML, and historical data has become integral to materials research. The efficiency of computational modelling is strongly affected by the choice of the numerical representation for describing the composition, structure and chemical elements. Structure controls the properties, but often only the composition of a candidate material is available. Existing elemental descriptors lack direct access to structural insights such as the coordination geometry of an element. In this study, we introduce Local Environment-induced Atomic Features, LEAFs, which incorporate information about the statistically preferred local coordination geometry for atoms in crystal structure into descriptors for chemical elements, enabling the modelling of materials solely as compositions without requiring knowledge of their crystal structure. In the crystal structure, each atomic site can be described by similarity to common local structural motifs; by aggregating these features of similarity from the experimentally verified crystal structures of inorganic materials, LEAFs formulate a set of descriptors for chemical elements and compositions. The direct connection of LEAFs to the local coordination geometry enables the analysis of ML model property predictions, linking compositions to the underlying structure-property relationships. We demonstrate the versatility of LEAFs in structure-informed property predictions for compositions, mapping of chemical space in structural terms, and prioritising elemental substitutions. Based on the latter for predicting crystal structures of binary ionic compounds, LEAFs achieve the state-of-the-art accuracy of 86 per cent. These results suggest that the structurally informed description of chemical elements and compositions developed in this work can effectively guide synthetic efforts in discovering new materials.
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