富锂层状Li-Mn-Ni-(Al)-O正极材料在空气中热处理后的相演变

Phase Evolution of Li-Rich Layered Li-Mn-Ni-(Al)-O Cathode Materials upon Heat Treatments in Air.

作者信息

Grins Jekabs, Jaworski Aleksander, Jøsang Leif Olav, Biendicho Jordi Jacas, Svensson Gunnar

机构信息

Arrhenius Laboratory, Department of Materials and Environmental Chemistry, Stockholm University, SE-10691 Stockholm, Sweden.

Cerpotech, Kvenildmyra 6, 7093 Heimdal, Norway.

出版信息

Materials (Basel). 2024 Dec 11;17(24):6056. doi: 10.3390/ma17246056.

DOI:10.3390/ma17246056

PMID:39769655

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11728093/

Abstract

The phase evolution of Li-rich Li-Mn-Ni-(Al)-O cathode materials upon heat treatments in the air at 900 °C was studied by X-ray and neutron powder diffraction. In addition, the structures of LiMnAl NiO, x = 0.0, 0.05, and 0.10, were refined from neutron powder diffraction data. For two-phase mixtures containing a monoclinic LiMnO type phase M and a rhombohedral LiMnNiO type phase R, the structures, compositions, and phase fractions change with heat treatment time. This is realized by the substitution mechanism 3Ni ↔ 2Li + 1Mn, which enables cation transport between the phases. A whole-powder pattern fitting analysis of size and strain broadening shows that strain broadening dominates. The X-ray domain size increases with heat treatment time and is larger than the sizes of the domains of M and R observed by electron microscopy. For heat-treated samples, the domain size is smaller for R than for M and decreases with increasing Al doping.

摘要

通过X射线和中子粉末衍射研究了富锂Li-Mn-Ni-(Al)-O正极材料在900℃空气中热处理后的相演变。此外，根据中子粉末衍射数据对x = 0.0、0.05和0.10的LiMnAlNiO结构进行了精修。对于包含单斜LiMnO型相M和菱面体LiMnNiO型相R的两相混合物，其结构、组成和相分数随热处理时间而变化。这是通过3Ni ↔ 2Li + 1Mn的取代机制实现的，该机制使阳离子能够在各相之间传输。尺寸和应变展宽的全粉末图案拟合分析表明，应变展宽占主导。X射线域尺寸随热处理时间增加，且大于通过电子显微镜观察到的M和R域的尺寸。对于热处理后的样品，R的域尺寸比M的小，且随Al掺杂量增加而减小。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d570/11728093/d07f85b989d6/materials-17-06056-g001.jpg

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富锂层状Li-Mn-Ni-(Al)-O正极材料在空气中热处理后的相演变

Phase Evolution of Li-Rich Layered Li-Mn-Ni-(Al)-O Cathode Materials upon Heat Treatments in Air.

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