The Formation, Detriment and Solution of Residual Lithium Compounds on Ni-Rich Layered Oxides in Lithium-Ion Batteries

Chen, Anqi; Wang, Kun; Li, Jiaojiao; Mao, Qinzhong; Xiao, Zhen; Zhu, D; Wang, Guoguang; Peng, Liao; He, Jian; You, Ya; Xia, Yang

doi:10.3389/fenrg.2020.593009

Cited by 32 publications

(25 citation statements)

References 102 publications

(135 reference statements)

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“…To achieve high energy densities (>250 Wh kg −1 ) on a cell level, layered Ni-rich oxide cathode active materials (CAMs), such as LiNi 1−x−y Co x Mn y O 2 (referred to as NCM or NMC in the battery community), are commonly employed and currently represent a hot topic in cathode R&D [1,2]. However, it has been recognized both in academia and industry that surface residuals, primarily carbonate and hydroxide species, remaining from the synthesis (use of excess reagents) or formed during storage and handling, play a critical role on their processability and cyclability [3][4][5][6][7]. Especially the carbonate contaminants have been thoroughly studied in the past and shown to contribute to gas evolution via chemical (equation ( 1)) and/or electrochemical decomposition (equation ( 2)), which can lead to problems with battery performance and safety [4,[8][9][10]:…”

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confidence: 99%

On the role of surface carbonate species in determining the cycling performance of all-solid-state batteries

et al. 2022

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This short Perspective summarizes recent findings on the role of residual lithium present on the surface of layered Ni-rich oxide cathode materials in liquid- and solid-electrolyte based batteries, with emphasis placed on the carbonate species. Challenges and future research opportunities in the development of carbonate-containing protective nanocoatings for inorganic solid-state battery applications are also discussed.

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confidence: 99%

On the role of surface carbonate species in determining the cycling performance of all-solid-state batteries

et al. 2022

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“…Regardless of the accelerating effect of the high cutoff voltage on its formation, Li 2 O has been observed across NMC, LiCoO 2 , and LMR cathodes under various electrochemical conditions, including simple immersion of the layered oxide in electrolyte without cycling. The maximum Li 2 O is generated at the activation of the cathode and progressively transforms to Li 2 CO 3 , LiOH, or LiF compounds as the electrochemical cycling proceeds. , …”

Section: Driving the Oxygen Lossmentioning

confidence: 99%

Oxygen Loss in Layered Oxide Cathodes for Li-Ion Batteries: Mechanisms, Effects, and Mitigation

et al. 2022

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Layered lithium transition metal oxides derived from LiMO 2 (M = Co, Ni, Mn, etc.) have been widely adopted as the cathodes of Li-ion batteries for portable electronics, electric vehicles, and energy storage. Oxygen loss in the layered oxides is one of the major factors leading to cycling-induced structural degradation and its associated fade in electrochemical performance. Herein, we review recent progress in understanding the phenomena of oxygen loss and the resulting structural degradation in layered oxide cathodes. We first present the major driving forces leading to the oxygen loss and then describe the associated structural degradation resulting from the oxygen loss. We follow this analysis with a discussion of the kinetic pathways that enable oxygen loss, and then we address the resulting electrochemical fade. Finally, we review the possible approaches toward mitigating oxygen loss and the associated electrochemical fade as well as detail novel analytical methods for probing the oxygen loss.

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“…This result suggests that Li 2 CO 3 tends to grow on the surface of Ni-rich cathodes (Figure 7(b)). Chemically active Ni 3+ tends to convert to Ni 2+ because this alleviates the local lattice distortion of the Ni-O octahedra, while also releasing some of the residual stress and reducing the system energy [81]. In addition, the highly reactive oxygen species will be accelerated with the reduction reaction of Ni 3+ [82].…”

Section: Mechanisms Of Air/water Instability Of Ni-richmentioning

confidence: 99%

Air/Water Stability Problems and Solutions for Lithium Batteries

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Chen

et al. 2022

Energy Mater Adv

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Recently, lithium-ion batteries (LIBs) have faced bottlenecks in terms of energy/power density and safety issues caused by flammable electrolytes. In this regard, all-solid-state batteries (ASSBs) may be one of the most promising solutions. However, many key battery materials (such as solid electrolytes (SEs), cathodes, and anodes) are unstable to air/water, which greatly limits their production, storage, transportation, practical applications, and the development of ASSBs. Herein, the research status on air/water stability of SEs, cathodes, and anodes is reviewed. The mechanisms for their air/water instability are revealed in details. The corresponding modification methods are also proposed, with emphasis on the construction strategies of air/water stable protective layers, including ex situ coatings and in situ reactions. Moreover, the application of air/water-stable protective layers in ASSBs is discussed correspondingly. Last but not least, the advantages and disadvantages of various protective layer construction strategies are analyzed, in which their applications in practical production are prospected.

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The Formation, Detriment and Solution of Residual Lithium Compounds on Ni-Rich Layered Oxides in Lithium-Ion Batteries

Cited by 32 publications

References 102 publications

On the role of surface carbonate species in determining the cycling performance of all-solid-state batteries

On the role of surface carbonate species in determining the cycling performance of all-solid-state batteries

Oxygen Loss in Layered Oxide Cathodes for Li-Ion Batteries: Mechanisms, Effects, and Mitigation

Air/Water Stability Problems and Solutions for Lithium Batteries

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