Litcius/Paper detail

Machine Learning Automated Analysis of Enormous Synchrotron X-ray Diffraction Datasets

Xiaodong Zhao, YiXuan Luo, Juejing Liu, Wenjun Liu, Kevin M. Rosso, Xiaofeng Guo, Tong Geng, Ang Li, Xin Zhang

2023The Journal of Physical Chemistry C18 citationsDOIOpen Access PDF

Abstract

X-ray diffraction (XRD) data analysis can be a time-consuming and laborious task. Deep neural network (DNN) based models trained with synthetic XRD patterns have been proven to be a highly efficient, accurate, and automated method for analyzing common XRD data collected from solid samples in ambient environments. However, it remains unclear whether synthetic XRD-based models can be effective in solving micro(μ)-XRD mapping data for in situ experiments involving liquid phases, which always have lower quality and significant artifacts. In this study, we collected μ-XRD mapping data from a LaCl 3 -calcite hydrothermal fluid system and trained two categories of models to analyze the experimental XRD patterns. The models trained solely with synthetic XRD patterns showed low accuracy (as low as 64%) when solving experimental μ-XRD mapping data. However, the accuracy of the DNN models significantly improved (90% or above) when we trained them with a data set containing both synthetic and a small number of labeled experimental μ-XRD patterns. This study highlights the importance of labeled experimental patterns in training DNN models to solve μ-XRD mapping data from in situ experiments involving liquid phases.

Topics & Concepts

Artificial neural networkDiffractionSynchrotronMaterials scienceArtificial intelligenceExperimental dataCalciteIn situX-ray crystallographyComputer scienceSynthetic dataPhase (matter)Sample (material)Pattern recognition (psychology)Analytical Chemistry (journal)Machine learningMineralogyPhysicsOpticsMathematicsChemistryStatisticsChromatographyQuantum mechanicsMeteorologyX-ray Diffraction in CrystallographyMachine Learning in Materials ScienceNuclear Physics and Applications