Grain Boundaries and Their Impact on Li Kinetics in Layered-Oxide Cathodes for Li-Ion Batteries

He, Xiaocong; Sun, Hong; Ding, Xiangdong; Zhao, Kejie

doi:10.1021/acs.jpcc.1c02400

Cited by 38 publications

(32 citation statements)

References 71 publications

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“…It is generally considered that the diffusion along interfaces is faster than that across interfaces, which has been demonstrated in SE Li 3 OCl 98 and cathode material LiNi 0.5 Mn 0.3 Co 0.2 O 2 . 99…”

Section: Short-circuit Diffusionmentioning

confidence: 99%

Review on the lithium transport mechanism in solid‐state battery materials

Chen

Zhang

2022

WIREs Comput Mol Sci

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The growing demands to mitigate climate change and environmental degradation stimulate the rapid developments of rechargeable lithium (Li) battery technologies. Fast Li transports in battery materials are of essential significance to ensure superior Li dynamical stability and rate performance of batteries. Herein, the Li transport mechanisms in solid‐state battery materials (SSBMs) are comprehensively summarized. The collective diffusion mechanisms in solid electrolytes are elaborated, which are further understood from multiple perspectives including lattice dynamics, crystalline structure, and electronic structure. With the exponentially improving performance of computers, atomistic simulations have been playing an increasingly important role in revealing and understanding the Li transport in SSBMs, bridging the gap between experimental phenomena and theoretical models. Theoretical and experimental characterization methods for Li transports are discussed. The design strategies toward fast Li transports are classified. Finally, a perspective on the achievements and challenges of probing Li transports is provided. This article is categorized under: Structure and Mechanism > Computational Materials Science

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Section: Short-circuit Diffusionmentioning

confidence: 99%

Review on the lithium transport mechanism in solid‐state battery materials

Chen

Zhang

2022

WIREs Comput Mol Sci

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“…Grain boundaries, including antiphase boundaries and twin boundaries, regulate the phase transformation process . Although experimentally investigating the grain boundaries can be challenging, prior computational works suggest that grain boundaries can hinder diffusion. − The mismatched volume change in different grains leads to crack formation along grain boundaries. , …”

Section: Origin Of Chemomechanical Degradationmentioning

confidence: 99%

Chemomechanics of Rechargeable Batteries: Status, Theories, and Perspectives

Vasconcelos

et al. 2022

Chem. Rev.

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109

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Chemomechanics is an old subject, yet its importance has been revived in rechargeable batteries where the mechanical energy and damage associated with redox reactions can significantly affect both the thermodynamics and rates of key electrochemical processes. Thanks to the push for clean energy and advances in characterization capabilities, significant research efforts in the last two decades have brought about a leap forward in understanding the intricate chemomechanical interactions regulating battery performance. Going forward, it is necessary to consolidate scattered ideas in the literature into a structured framework for future efforts across multidisciplinary fields. This review sets out to distill and structure what the authors consider to be significant recent developments on the study of chemomechanics of rechargeable batteries in a concise and accessible format to the audiences of different backgrounds in electrochemistry, materials, and mechanics. Importantly, we review the significance of chemomechanics in the context of battery performance, as well as its mechanistic understanding by combining electrochemical, materials, and mechanical perspectives. We discuss the coupling between the elements of electrochemistry and mechanics, key experimental and modeling tools from the small to large scales, and design considerations. Lastly, we provide our perspective on ongoing challenges and opportunities ranging from quantifying mechanical degradation in batteries to manufacturing battery materials and developing cyclic protocols to improve the mechanical resilience.

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“…Furthermore, rechargeable batteries have been widely studied as carbon-neutral energy sources. In particular, all-solid-state lithium ion batteries, wherein flammable organic electrolytes are replaced with non-flammable inorganic electrolytes, have received much attention for reducing CO 2 emissions. − In this system, various sulfide-based solid electrolytes, for example, Li 2 S–P 2 S 5 glass ceramics and hali-chalcogenide Li 6 PS 5 Cl (argyrodite phase) exhibited ultrahigh Li + ion conductivity and a wide electrochemical window. − ,− Sulfide-based solid electrolytes show high chemical stability in a low humidity atmosphere, indicating that the materials should be administrated under dry air or inert gas flow conditions. However, sulfide-based materials hydrolyze with water in air to generate H 2 S gas .…”

Section: Introductionmentioning

confidence: 99%

Hydration of LiOH and LiCl─Near-Infrared Spectroscopic Analysis

et al. 2021

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The hydration behavior of LiOH, LiOH·H2O, and LiCl was observed by near-infrared (NIR) spectroscopy. Anhydrous LiOH showed two absorption bands at 7340 and 7171 cm–1. These NIR bands were assigned to the first overtone of surface hydroxyls and interlayer hydroxyls of LiOH, respectively. LiOH·H2O showed two absorption bands at 7137 and 6970 cm–1. These NIR bands were assigned to the first overtone of interlayer hydroxyls and H2O molecules coordinated with Li+, respectively. The interlayer OH– and the coordinated H2O of LiOH·H2O were not modified even when the LiOH·H2O was exposed to air. In contrast, anhydrous LiOH was slowly hydrated for several hours, to form LiOH·H2O under ambient conditions (RH 60%). Kinetic analysis showed that the hydration of the interlayer OH– of LiOH proceeded as a second-order reaction, indicating the formation of intermediate species[Li(H2O) x (OH)4]3– (x = 1 or 2). However, the hydration of the LiOH surface did not follow a second-order reaction because the chemisorption of H2O molecules onto the defect sites of the LiOH surface does not need to crossover the energy barrier. Furthermore, we succeeded in observing the hydration of deliquescent LiCl, including the formation of LiCl solution for several minutes by NIR spectroscopy.

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Grain Boundaries and Their Impact on Li Kinetics in Layered-Oxide Cathodes for Li-Ion Batteries

Cited by 38 publications

References 71 publications

Review on the lithium transport mechanism in solid‐state battery materials

Review on the lithium transport mechanism in solid‐state battery materials

Chemomechanics of Rechargeable Batteries: Status, Theories, and Perspectives

Hydration of LiOH and LiCl─Near-Infrared Spectroscopic Analysis

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