通过单晶富镍正极材料共掺杂策略实现高能锂金属电池

Enabling high energy lithium metal batteries via single-crystal Ni-rich cathode material co-doping strategy.

作者信息

Ou Xing, Liu Tongchao, Zhong Wentao, Fan Xinming, Guo Xueyi, Huang Xiaojing, Cao Liang, Hu Junhua, Zhang Bao, Chu Yong S, Hu Guorong, Lin Zhang, Dahbi Mouad, Alami Jones, Amine Khalil, Yang Chenghao, Lu Jun

机构信息

Guangzhou Key Laboratory for Surface Chemistry of Energy Materials, New Energy Research Institute, School of Environment and Energy, South China University of Technology, Guangzhou, 510006, China.

School of Metallurgy and Environment, Central South University, Changsha, 410083, China.

出版信息

Nat Commun. 2022 Apr 28;13(1):2319. doi: 10.1038/s41467-022-30020-4.

DOI:10.1038/s41467-022-30020-4

PMID:35484128

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9050889/

Abstract

High-capacity Ni-rich layered oxides are promising cathode materials for secondary lithium-based battery systems. However, their structural instability detrimentally affects the battery performance during cell cycling. Here, we report an Al/Zr co-doped single-crystalline LiNiCoMnO (SNCM) cathode material to circumvent the instability issue. We found that soluble Al ions are adequately incorporated in the SNCM lattice while the less soluble Zr ions are prone to aggregate in the outer SNCM surface layer. The synergistic effect of Al/Zr co-doping in SNCM lattice improve the Li-ion mobility, relief the internal strain, and suppress the Li/Ni cation mixing upon cycling at high cut-off voltage. These features improve the cathode rate capability and structural stabilization during prolonged cell cycling. In particular, the Zr-rich surface enables the formation of stable cathode-electrolyte interphase, which prevent SNCM from unwanted reactions with the non-aqueous fluorinated liquid electrolyte solution and avoid Ni dissolution. To prove the practical application of the Al/Zr co-doped SNCM, we assembled a 10.8 Ah pouch cell (using a 100 μm thick Li metal anode) capable of delivering initial specific energy of 504.5 Wh kg at 0.1 C and 25 °C.

摘要

高容量富镍层状氧化物是用于二次锂基电池系统的有前景的阴极材料。然而，它们的结构不稳定性在电池循环过程中对电池性能产生不利影响。在此，我们报道一种铝/锆共掺杂的单晶LiNiCoMnO（SNCM）阴极材料以规避不稳定性问题。我们发现可溶的铝离子充分掺入到SNCM晶格中，而较难溶的锆离子易于在SNCM外层表面聚集。铝/锆在SNCM晶格中的共掺杂协同效应提高了锂离子迁移率、缓解了内部应变，并在高截止电压下循环时抑制了锂/镍阳离子混合。这些特性提高了阴极倍率性能以及在长时间电池循环过程中的结构稳定性。特别地，富含锆的表面能够形成稳定的阴极-电解质界面，这防止了SNCM与非水氟化液体电解质溶液发生不必要的反应并避免了镍的溶解。为了证明铝/锆共掺杂SNCM的实际应用，我们组装了一个10.8 Ah软包电池（使用100μm厚的锂金属阳极），其在0.1 C和25°C下能够提供504.5 Wh kg的初始比能量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4e7c/9050889/dd7333b9edb9/41467_2022_30020_Fig1_HTML.jpg

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通过单晶富镍正极材料共掺杂策略实现高能锂金属电池

Enabling high energy lithium metal batteries via single-crystal Ni-rich cathode material co-doping strategy.

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