粉末衍射
晶体结构
结晶学
材料科学
Crystal(编程语言)
计算机科学
化学
程序设计语言
作者
Qingsi Lai,Fanjie Xu,Lin Yao,Zhifeng Gao,Siyuan Liu,Hongshuai Wang,Shuqi Lu,Di He,Liwei Wang,Linfeng Zhang,Cheng Wang,Guolin Ke
出处
期刊:Advanced Science
[Wiley]
日期:2025-01-04
卷期号:12 (8): e2410722-e2410722
被引量:18
标识
DOI:10.1002/advs.202410722
摘要
Powder X-ray diffraction (PXRD) is a prevalent technique in materials characterization. While the analysis of PXRD often requires extensive human manual intervention, and most automated method only achieved at coarse-grained level. The more difficult and important task of fine-grained crystal structure prediction from PXRD remains unaddressed. This study introduces XtalNet, the first equivariant deep generative model for end-to-end crystal structure prediction from PXRD. Unlike previous crystal structure prediction methods that rely solely on composition, XtalNet leverages PXRD as an additional condition, eliminating ambiguity and enabling the generation of complex organic structures with up to 400 atoms in the unit cell. XtalNet comprises two modules: a Contrastive PXRD-Crystal Pretraining (CPCP) module that aligns PXRD space with crystal structure space, and a Conditional Crystal Structure Generation (CCSG) module that generates candidate crystal structures conditioned on PXRD patterns. Evaluation on two MOF datasets (hMOF-100 and hMOF-400) demonstrates XtalNet's effectiveness. XtalNet achieves a top-10 Match Rate of 90.2% and 79% for hMOF-100 and hMOF-400 in conditional crystal structure prediction task, respectively. XtalNet enables the direct prediction of crystal structures from experimental measurements, eliminating the need for manual intervention and external databases. This opens up new possibilities for automated crystal structure determination and the accelerated discovery of novel materials.
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