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无序岩盐阴极中的结构演变

Structural Evolution in Disordered Rock Salt Cathodes.

作者信息

Li Tianyu, Geraci Tullio S, Koirala Krishna Prasad, Zohar Arava, Bassey Euan N, Chater Philip A, Wang Chongmin, Navrotsky Alexandra, Clément Raphaële J

机构信息

Materials Department, University of California Santa Barbara, Santa Barbara 93106, California, United States.

Materials Research Laboratory, University of California Santa Barbara, Santa Barbara 93106, California, United States.

出版信息

J Am Chem Soc. 2024 Sep 4;146(35):24296-24309. doi: 10.1021/jacs.4c04639. Epub 2024 Aug 22.

DOI:10.1021/jacs.4c04639
PMID:39172075
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11378274/
Abstract

Li-excess Mn-based disordered rock salt oxides (DRX) are promising Li-ion cathode materials owing to their cost-effectiveness and high theoretical capacities. It has recently been shown that Mn-rich DRX LiMnMO ( ≥ 0.5, M are hypervalent ions such as Ti and Nb) exhibit a gradual capacity increase during the first few charge-discharge cycles, which coincides with the emergence of spinel-like domains within the long-range DRX structure coined as "δ phase". Here, we systematically study the structural evolution upon heating of Mn-based DRX at different levels of delithiation to gain insight into the structural rearrangements occurring during battery cycling and the mechanism behind δ phase formation. We find in all cases that the original DRX structure relaxes to a δ phase, which in turn leads to capacity enhancement. Synchrotron X-ray and neutron diffraction were employed to examine the structure of the δ phase, revealing that selective migration of Li and Mn/Ti cations to different crystallographic sites within the DRX structure leads to the observed structural rearrangements. Additionally, we show that both Mn-rich ( ≥ 0.5) and Mn-poor ( < 0.5) DRX can thermally relax into a δ phase after delithiation, but the relaxation processes in these distinct compositions lead to different domain structures. Thermochemical studies and in situ heating XRD experiments further indicate that the structural relaxation has a larger thermodynamic driving force and a lower activation energy for Mn-rich DRX, as compared to Mn-poor systems, which underpins why this structural evolution is only observed for Mn-rich systems during battery cycling.

摘要

富锂锰基无序岩盐氧化物(DRX)因其成本效益和高理论容量而成为有前景的锂离子阴极材料。最近的研究表明,富锰的DRX LiMnMO(≥0.5,M为高价离子,如Ti和Nb)在最初的几个充放电循环中表现出容量逐渐增加的现象,这与在长程DRX结构中出现的类似尖晶石的区域(称为“δ相”)相吻合。在此,我们系统地研究了不同脱锂水平下锰基DRX加热时的结构演变,以深入了解电池循环过程中发生的结构重排以及δ相形成背后的机制。我们发现在所有情况下,原始的DRX结构都会弛豫到δ相,这反过来又导致容量增加。利用同步加速器X射线和中子衍射来研究δ相的结构,结果表明Li和Mn/Ti阳离子选择性迁移到DRX结构内不同的晶体学位置导致了所观察到的结构重排。此外,我们表明,富锰(≥0.5)和贫锰(<0.5)的DRX在脱锂后都可以热弛豫到δ相,但这些不同组成中的弛豫过程会导致不同的畴结构。热化学研究和原位加热XRD实验进一步表明,与贫锰体系相比,富锰DRX的结构弛豫具有更大的热力学驱动力和更低的活化能,这解释了为什么在电池循环过程中仅在富锰体系中观察到这种结构演变。

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