Sodium Niobate with a Large Interlayer Spacing: A Fast‐Charging, Long‐Life, and Low‐Temperature Friendly Lithium‐Storage Material

Niobate Li+‐storage anode materials with shear ReO3 crystal structures have attracted intensive attention due to their inherent safety and large capacities. However, they generally suffer from limited rate performance, cyclic stability, and temperature adaptability, which are rooted in their insuffi...

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Published in:Advanced science 2023-07, Vol.10 (20), p.e2300583-n/a
Main Authors: Gao, Jiazhe, Yang, Liting, Huang, Cihui, Liang, Guisheng, Lei, Yi, Li, Songjie, Wang, Wenze, Ou, Yinjun, Gao, Shangfu, Liu, Xuehua, Cheng, Yifeng, Zhang, Jincang, Liu, Zhongzhu, Guo, Aiming, Monteiro, Robson, Parreira, Luanna, Ribas, Rogerio, Lin, Chunfu, Wu, Limin, Che, Renchao
Format: Article
Language:English
Subjects:
Crystal structure
Electrodes
Electrolytes
Graphite
in situ characterization
interlayer spacing
lithium‐storage mechanism
Nanomaterials
niobate
Retention
Temperature
temperature‐dependent lithium‐storage property
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Summary:Niobate Li+‐storage anode materials with shear ReO3 crystal structures have attracted intensive attention due to their inherent safety and large capacities. However, they generally suffer from limited rate performance, cyclic stability, and temperature adaptability, which are rooted in their insufficient interlayer spacings. Here, sodium niobate (NaNb13O33) micron‐sized particles are developed as a new anode material owning the largest interlayer spacing among the known shear ReO3‐type niobates. The large interlayer spacing of NaNb13O33 enables very fast Li+ diffusivity, remarkably contributing to its superior rate performance with a 2500 to 125 mA g−1 capacity percentage of 63.2%. Moreover, its large interlayer spacing increases the volume‐accommodation capability during lithiation, allowing small unit‐cell‐volume variations (maximum 6.02%), which leads to its outstanding cyclic stability with 87.9% capacity retention after as long as 5000 cycles at 2500 mA g−1. Its cyclic stability is the best in the research field of niobate micron‐sized particles, and comparable to that of “zero‐strain” Li4Ti5O12. At a low temperature of −10 °C, it also exhibits high rate performance with a 1250 to 125 mA g−1 capacity percentage of 65.6%, and even better cyclic stability with 105.4% capacity retention after 5000 cycles at 1250 mA g−1. These comprehensively good electrochemical results pave the way for the practical application of NaNb13O33 in high‐performance Li+ storage. NaNb13O33 micron‐sized particles are explored as a practical Li+‐storage anode material with comprehensively good electrochemical properties and broad temperature adaptability. This new niobate owns the largest interlayer spacing among the known shear ReO3‐type niobates. This merit leads to very fast Li+ diffusivity, notable intercalation‐pseudocapacitive behavior, and small unit‐cell‐volume variations, greatly benefiting the rate performance, cyclic stability, and low‐temperature electrochemical properties.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202300583