Interface‐Targeting Carrier‐Catalytic Integrated Design Contributing to Lithium Dihalide‐Rich SEI toward High Interface Stability for Long‐Life Solid‐State Lithium‐Metal Batteries

Zhou, Xuanyi; Huang, Fenfen; Zhang, Xuedong; Zhang, Biao; Cui, Yingjie; Wang, Zehua; Yang, Qiong; Ma, Zengsheng; Liu, Jun

doi:10.1002/ange.202401576

Angewandte Chemie

2024

DOI: 10.1002/ange.202401576

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Interface‐Targeting Carrier‐Catalytic Integrated Design Contributing to Lithium Dihalide‐Rich SEI toward High Interface Stability for Long‐Life Solid‐State Lithium‐Metal Batteries

Xuanyi Zhou,

Fenfen Huang,

Xuedong Zhang

et al.

Abstract: The generation of solid electrolyte interphase (SEI) largely determines the comprehensive performance of all‐solid‐state batteries. Herein, a novel “carrier‐catalytic” integrated design is strategically exploited to in situ construct a stable LiF‐LiBr rich SEI by improving the electron transfer kinetics to accelerate the bond‐breaking dynamics. Specifically, the high electron transport capacity of Br‐TPOM skeleton increases the polarity of C‐Br, thus promoting the generation of LiBr. Then, the enhancement of e… Show more

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Cited by 7 publications

References 60 publications

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Intermolecular Interaction Mediated Potassium Ion Intercalation Chemistry in Ether‐Based Electrolyte for Potassium‐Ion Batteries

Xie,

Liang,

Kumar

et al. 2024

Adv Funct Materials

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Electrolyte design is indeed a highly effective strategy to improve battery performance. However, identifying the intermolecular interaction in electrolyte solvation structure is rarely reported in potassium‐ion batteries. Herein, it is discovered that a solvent‐solvent intermolecular interaction can be formed when introducing the cyclopentylmethyl ether (CPME) solvent into the commonly used 1,2‐dimethoxyethane (DME)‐based electrolytes. Such interaction is not only analyzed by 2D 1H‐1H correlation spectroscopy for the first time but also found that it can weaken the K+‐DME interaction significantly, consequently enabling a reversible K+ (de‐)intercalation within the graphite. By employing this strategy without using any fluorine‐based solvent, a new fluorine‐free and low‐concentration ether‐based electrolyte is designed, which is not only compatible with graphite but also facilitates the design of high‐energy‐density and safe potassium ion sulfur batteries. A novel molecular interfacial model is further presented to analyze the interfacial behaviors of K+‐solvent‐anion complexes on the electrode surface that are affected by intermolecular interactions, elucidating the reasons behind the superior electrolyte compatibility and graphite electrode performance at the molecular scale. This work sheds some light on the critical role of solvent–solvent interactions in electrolyte design for potassium‐ion batteries and provides valuable insights for engineering and enhancing the performance of electrolytes and batteries.

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Intermolecular Interaction Mediated Potassium Ion Intercalation Chemistry in Ether‐Based Electrolyte for Potassium‐Ion Batteries

Xie,

Liang,

Kumar

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

UV‐Triggered In Situ Formation of a Robust SEI on Black Phosphorus for Advanced Energy Storage: Boosting Efficiency and Safety via Rapid Charge Integration Plasticity

Wang,

Liu,

et al. 2024

Advanced Energy Materials

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Black phosphorus (BP) emerges as a highly promising electrode material for next generation of energy‐storage systems. Yet, its full potential is hindered by the instability of the solid‐electrolyte interphase (SEI) and the inflammability of its liquid systems. Here a pioneering UV‐induced in situ strategy is introduced for SEI construction, which leverages rapid electron supply to fracture sulfur‐dihalide bonds. This technique yields internal dihalide inorganic components and an external polymer segment, with any excess organic material being purged through pores. The (E)‐2‐chloro‐4‐((3′‐chloro‐4′‐hydroxyphenyl)diazinyl)phenyl acrylate (CA), with chlorine‐terminated groups, is initially in situ transformed into a flame‐retardant phenyl carboxylic acid (PCA), and then encapsulated within an ultrathin BP nanostructure, further nested in nitrogen (N), boron (B) co‐doped carbon (C) sheets that accommodate cobalt (Co) single atoms/nanoclusters (Co‐NBC). The Co‐NBC@BP@PCA construct demonstrates an impressive initial Coulombic efficiency (ICE) of 99.1% and maintains exceptional stabilities in terms of mechanical, chemical, and electrochemical performancecritical for prolonged cycle and calendar life. This research sheds light on the interplay between the rapid charge supply integrated in situ plasticity (RSIP) approach and the proactive establishment of an artificial SEI layer, offering profound insights into enhancing the durability and providing a solid foundation for advancements in energy storage technology.

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Li₂MoO₄ Tailored Anion‐enhanced Solvation Sheath Layer Promotes Solution‐phase Mediated Li‐O₂ Batteries

Zhang,

Hu,

Lai

et al. 2024

Angewandte Chemie

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The high overpotential of Li‐O2 batteries (LOBs) is primarily triggered by sluggish charge transfer kinetics at the reaction interfaces. A typical LiBr redox mediator (RM) catalyst can effectively reduce the battery’s overpotential. However, it is prone to shuttling and corroding the Li anode, leading to RM loss and reduced energy efficiency. To address these challenges, we introduced Li2MoO4 into the LiBr‐containing electrolyte to promote the solution‐phase mediated LOBs. This addition tailors the anion‐enhanced Li+ solvation sheath layer and forms a robust anion‐derived solid electrolyte interphases (SEI) on the Li anode. The robust SEI effectively mitigates the corrosion of soluble Br3‐/Br2 and attacks by highly reactive oxygen species. Additionally, the dispersed and high‐density Li2MoO4 exhibits strong adsorption capabilities for O2/LiO2 and Br‐related species during the discharge/charge process, thereby promoting the growth and decomposition of Li2O2 in the solution phase and inhibiting the shuttle effect of Br‐related species in LOBs. Consequently, the LOBs demonstrate exceptional cycling stability (415 cycles) and high energy efficiency (86.2%), paving the way for the sustainable development and practical application of these battery systems.

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Interface‐Targeting Carrier‐Catalytic Integrated Design Contributing to Lithium Dihalide‐Rich SEI toward High Interface Stability for Long‐Life Solid‐State Lithium‐Metal Batteries

Cited by 7 publications

References 60 publications

Intermolecular Interaction Mediated Potassium Ion Intercalation Chemistry in Ether‐Based Electrolyte for Potassium‐Ion Batteries

Intermolecular Interaction Mediated Potassium Ion Intercalation Chemistry in Ether‐Based Electrolyte for Potassium‐Ion Batteries

UV‐Triggered In Situ Formation of a Robust SEI on Black Phosphorus for Advanced Energy Storage: Boosting Efficiency and Safety via Rapid Charge Integration Plasticity

Li₂MoO₄ Tailored Anion‐enhanced Solvation Sheath Layer Promotes Solution‐phase Mediated Li‐O₂ Batteries

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Interface‐Targeting Carrier‐Catalytic Integrated Design Contributing to Lithium Dihalide‐Rich SEI toward High Interface Stability for Long‐Life Solid‐State Lithium‐Metal Batteries

Cited by 7 publications

References 60 publications

Intermolecular Interaction Mediated Potassium Ion Intercalation Chemistry in Ether‐Based Electrolyte for Potassium‐Ion Batteries

Intermolecular Interaction Mediated Potassium Ion Intercalation Chemistry in Ether‐Based Electrolyte for Potassium‐Ion Batteries

UV‐Triggered In Situ Formation of a Robust SEI on Black Phosphorus for Advanced Energy Storage: Boosting Efficiency and Safety via Rapid Charge Integration Plasticity

Li2MoO4 Tailored Anion‐enhanced Solvation Sheath Layer Promotes Solution‐phase Mediated Li‐O2 Batteries

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Product

Resources

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Li₂MoO₄ Tailored Anion‐enhanced Solvation Sheath Layer Promotes Solution‐phase Mediated Li‐O₂ Batteries