Imaging inter - and intra-particle features in crystalline cathode materials for Li-ion batteries using nano-focused beam techniques at 4th generation synchrotron sources

Microstructures Pub Date : 2024-07-24 DOI:10.20517/microstructures.2024.19

Mattia Colalongo, Nikita Vostrov, Isaac Martens, E. Zatterin, Marie-Ingrid Richard, Francois Cadiou, Quentin Jacquet, J. Drnec, Steven J. Leake, Tanja Kallio, Xiaobo Zhu, S. Lyonnard, T. Schulli

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Abstract

The necessity of mapping crystal defects in battery materials after synthesis is crucial in understanding heterogeneity within a single crystal domain and among particles to develop superior crystal quality materials. Numerous imaging techniques have been developed over the past years to study these materials at the nanoscale. However, most of them use electron beams which demand many hours of sample preparation, and they are incompatible with the investigation of batteries under realistic working conditions. Techniques such as Scanning X-ray Diffraction Imaging (Scanning X-ray Diffraction Microscopy) or Bragg Coherent Diffraction Imaging are increasingly available on the latest generation synchrotron sources. Their progressive deployment will allow for a standardized method for imaging crystal lattice imperfections such as lattice tilt and strain in individual particles without any prior sample preparation. In this paper, we exploited Scanning X-ray Diffraction Microscopy to probe the strain variation in single crystals and polycrystalline particles and Bragg Coherent Diffraction Imaging to reconstruct the volume of a single crystal particle. Presented case studies were performed on particles of different active cathode materials ($$ \rm{LiNi_{0.6}Mn_{0.2}Co_{0.2}O_{2}} $$ , $$ \rm{LiNiO_{2}} $$ and $$ \rm{LiMn_{1.5}Ni_{0.5}O_{4}} $$ ); however, these techniques can also be employed on other battery components for a more holistic structural understanding of used materials and (de)lithiation dynamics on the microscale.

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利用第四代同步辐射源的纳米聚焦光束技术成像锂离子电池晶体阴极材料的粒子间和粒子内特征

电池材料在合成后必须绘制晶体缺陷图，这对于了解单晶域内和颗粒间的异质性以开发优质晶体材料至关重要。在过去的几年里，已经开发出许多成像技术，用于在纳米尺度上研究这些材料。然而，这些技术大多使用电子束，需要耗费大量时间制备样品，而且不适合在实际工作条件下研究电池。扫描 X 射线衍射成像（扫描 X 射线衍射显微镜）或布拉格相干衍射成像等技术越来越多地应用于最新一代同步辐射源。它们的逐步应用将为晶格缺陷成像（如单个颗粒中的晶格倾斜和应变）提供标准化方法，而无需事先制备样品。在本文中，我们利用扫描 X 射线衍射显微镜探测单晶和多晶颗粒的应变变化，并利用布拉格相干衍射成像重建单晶颗粒的体积。所介绍的案例研究是针对不同活性阴极材料（$$ \rm{LiNi_{0.6}Mn_{0.2}Co_{0.2}O_{2}} 、$$ \rm{LiNi_{0.6}Mn_{0.2}Co_{0.2}O_{2}} ）的颗粒进行的。$$ ， $$ \rm{LiNiO_{2}}$$ 和 $$ \rm{LiMn_{1.5}Ni_{0.5}O_{4}}} ）。然而，这些技术也可用于其他电池组件，以便更全面地了解所用材料的结构和微尺度上的（脱）锂化动力学。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microstructures

CiteScore

3.10

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0.00%

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