In Situ Construction of an Ultra‐Stable Conductive Composite Interface for High‐Voltage All‐Solid‐State Lithium Metal Batteries

Shi, Kai; Wan, Zipei; Lu, Yang; Zhang, Yiwen; Huang, Yanfei; Su, Shiming; Xia, Heyi; Jiang, Keling; Shen, Luyan; Huiuk, Yi; Zhang, Shiqi; Yu, Jing; Ren, Fuzeng; He, Yan‐Bing; Kang, Feiyu

doi:10.1002/anie.202000547

Cited by 132 publications

(67 citation statements)

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“…Impeded by the notoriously interfacial issues between ISEs and electrodes, it's hard for them to give a full play to their superiorities. Much efforts have been paid to reconcile these dilemmas with the aid of fabricating polymer buffer, [13][14][15] constructing heterogeneous metal or metal-oxide/nitride layer to form Lialloy interphase, [16][17][18] incorporating carbon-matrix materials into Li metal etc., [19,20] and yielding remarkable results. Nonetheless, these solutions often require extremely expensive and sophisticated equipment along with gigantic energy consumption during the handling process, thus obstructing the large-scale treatments in industry.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical Composite‐Solid‐Electrolyte with High Electrochemical Stability and Interfacial Regulation for Boosting Ultra‐Stable Lithium Batteries

Sun

Yao

et al. 2020

Adv Funct Materials

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Solid‐state electrolytes have drawn enormous attention to reviving lithium batteries but have also been barricaded in lower ionic conductivity at room temperature, awkward interfacial contact, and severe polarization. Herein, a sort of hierarchical composite solid electrolyte combined with a “polymer‐in‐separator” matrix and “garnet‐at‐interface” layer is prepared via a facile process. The commercial polyvinylidene fluoride‐based separator is applied as a host for the polymer‐based ionic conductor, which concurrently inhibits over‐polarization of polymer matrix and elevates high‐voltage compatibility versus cathode. Attached on the side, the compact garnet (Li6.4La3Zr1.4Ta0.6O12) layer is glued to physically inhibit the overgrowth of lithium dendrite and regulate the interfacial electrochemistry. At 25 °C, the electrolyte exhibits a high ionic conductivity of 2.73 × 10−4 S cm−1 and a decent electrochemical window of 4.77 V. Benefiting from this elaborate electrolyte, the symmetrical Li||Li battery achieves steady lithium plating/stripping more than 4800 h at 0.5 mA cm−2 without dendrites and short‐circuit. The solid‐state batteries deliver preferable capacity output with outstanding cycling stability (95.2% capacity retained after 500 cycles, 79.0% after 1000 cycles at 1 C) at ambient temperature. This hierarchical structure design of electrolyte may reveal great potentials for future development in fields of solid‐state metal batteries.

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Section: Introductionmentioning

confidence: 99%

Hierarchical Composite‐Solid‐Electrolyte with High Electrochemical Stability and Interfacial Regulation for Boosting Ultra‐Stable Lithium Batteries

Sun

Yao

et al. 2020

Adv Funct Materials

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“…[13,33,36,39] Interfacial engineering that might enable halide SEs working with Li metal anode would be an interesting future research. [8,[66][67][68][69][70] The mechanochemically prepared halide SEs, Li 2+x Zr 1−x Fe x Cl 6 , were applied for cathodes using LiCoO 2 without any protective coating layers in all-solid-state cells tested at 30 °C (Figure 4a-f). Figure 4a shows first-cycle charge-discharge voltage profiles at 0.1C (16 mA Cl showed a distinctly different feature at the beginning of first charge compared with that which employed halide SEs: the sloping voltage profile starting at ≈3.2 V (vs Li/Li + ) (indicated by an arrow) confirmed the poor electrochemical oxidation stability of sulfide SEs.…”

mentioning

confidence: 99%

New Cost‐Effective Halide Solid Electrolytes for All‐Solid‐State Batteries: Mechanochemically Prepared Fe³⁺‐Substituted Li₂ZrCl₆

Kwak

Han

Lyoo

et al. 2021

Advanced Energy Materials

151

168

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, 0.7Li(CB 9 H 10)−0.3Li(CB 11 H 12), 6.7 mS cm −1), [11,12] and halides (e.g., Li 3 YX 6 [X = Cl, Br], 0.51-1.7 mS cm −1). [13,14] Thus far, oxide and sulfide SEs have been the most commonly investigated candidates. However, their pros and cons counteract each other. Oxide SEs possess high intrinsic electrochemical oxidation stabilities and relatively acceptable chemical stabilities; however, owing to their brittle nature, it is difficult to integrate them in devices. [3,10,15-17] On the other hand, the most important advantage of sulfide SEs, that is, mechanical deformability, which enables scalable cold-pressing-based fabrication protocols, is offset by their poor (electro)chemical stabilities. [3,16,18-20] On exposing sulfide SEs to humid air, the evolution of toxic H 2 S gases occurs. [21-26] Moreover, sulfide SEs exhibit oxidative decomposition at <3 V (vs Li/Li +) and are also incompatible with conventional layered LiMO 2 (M = Ni, Co, Mn, and Al) cathodes. [16,19,27] This issue can be alleviated by using protective coatings, such as LiNbO 3 and Li 3−x B 1−x C x O 3 ; [7,27] however, this constitutes additional processing costs. Furthermore, the oxidative decomposition of sulfide SEs at the surface of conductive carbon additives is unavoidable. [28-31] Recently, through reinvestigations on halide SEs, several compounds exhibiting Li + conductivities exceeding 10 −4 S cm −1 have been identified. [13,32−36] Asano and coworkers reported that trigonal Li 3 YCl 6 and monoclinic Li 3 YBr 6 showed high Li + Owing to the combined advantages of sulfide and oxide solid electrolytes (SEs), that is, mechanical sinterability and excellent (electro)chemical stability, recently emerging halide SEs such as Li 3 YCl 6 are considered to be a game changer for the development of all-solid-state batteries. However, the use of expensive central metals hinders their practical applicability. Herein, a new halide superionic conductors are reported that are free of rare-earth metals: hexagonal close-packed (hcp) Li 2 ZrCl 6 and Fe 3+-substituted Li 2 ZrCl 6 , derived via a mechanochemical method. Conventional heat treatment yields cubic close-packed monoclinic Li 2 ZrCl 6 with a low Li + conductivity of 5.7 × 10 −6 S cm −1 at 30 °C. In contrast, hcp Li 2 ZrCl 6 with a high Li + conductivity of 4.0 × 10 −4 S cm −1 is derived via ball-milling. More importantly, the aliovalent substitution of Li 2 ZrCl 6 with Fe 3+ , which is probed by complementary analyses using X-ray diffraction, pair distribution function, X-ray absorption spectroscopy, and Raman spectroscopy measurements, drastically enhances the Li + conductivity up to ≈1 mS cm −1 for Li 2.25 Zr 0.75 Fe 0.25 Cl 6. The superior interfacial stability when using Li 2+x Zr 1−x Fe x Cl 6 , as compared to that when using conventional Li 6 PS 5 Cl, is proved. Furthermore, an excellent electrochemical performance of the all-solid-state batteries is achieved via the combination of Li 2 ZrCl 6 and single-crystalline LiNi 0.88 Co 0.11 Al 0.01 O 2 .

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“…For example, Huo et al [124] introduced a Cu 3 N interlayer into LLZO using magnetic sputtering to react with Li to form a mixed conductive layer consisting of Li 3 N and Cu, resulting in a decrease in apparent LLZO/Li interfacial resistance from 1138.5 to 83 Ω cm 2 and a critical current density of 1.2 mA cm −2 . Similarly, a Li 3 N-Zn (or Li 3 N-Sn) composite interlayer was successfully introduced between LLZO and Li through an in situ reaction between Zn(NO 3 ) 2 and Li (or SnN x and Li) [125,126]. The formation of mixed conductive layers through electrode modification is also feasible.…”

Section: Compositional Modificationmentioning

confidence: 99%

Electrolyte/Electrode Interfaces in All-Solid-State Lithium Batteries: A Review

Pang

Pan

Yang

et al. 2021

Electrochem. Energ. Rev.

158

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All-solid-state lithium batteries are promising next-generation energy storage devices that have gained increasing attention in the past decades due to their huge potential towards higher energy density and safety. As a key component, solid electrolytes have also attracted significant attention and have experienced major breakthroughs, especially in terms of Li-ion conductivity. However, the poor electrode compatibility of solid electrolytes can lead to the degradation of electrolyte/electrode interfaces, which is the major cause for failure in all-solid-state lithium batteries. To address this, this review will summarize the indepth understanding of physical and chemical interactions between electrolytes and electrodes with a focus on the contact, charge transfer and Li dendrite formation occurring at electrolyte/electrode interfaces. Based on mechanistic analyses, this review will also briefly present corresponding strategies to enhance electrolyte/electrode interfaces through compositional modifications and structural designs. Overall, the comprehensive insights into electrolyte/electrode interfaces provided by this review can guide the future investigation of all-solid-state lithium batteries.

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In Situ Construction of an Ultra‐Stable Conductive Composite Interface for High‐Voltage All‐Solid‐State Lithium Metal Batteries

Cited by 132 publications

References 50 publications

Hierarchical Composite‐Solid‐Electrolyte with High Electrochemical Stability and Interfacial Regulation for Boosting Ultra‐Stable Lithium Batteries

Hierarchical Composite‐Solid‐Electrolyte with High Electrochemical Stability and Interfacial Regulation for Boosting Ultra‐Stable Lithium Batteries

New Cost‐Effective Halide Solid Electrolytes for All‐Solid‐State Batteries: Mechanochemically Prepared Fe³⁺‐Substituted Li₂ZrCl₆

Electrolyte/Electrode Interfaces in All-Solid-State Lithium Batteries: A Review

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In Situ Construction of an Ultra‐Stable Conductive Composite Interface for High‐Voltage All‐Solid‐State Lithium Metal Batteries

Cited by 132 publications

References 50 publications

Hierarchical Composite‐Solid‐Electrolyte with High Electrochemical Stability and Interfacial Regulation for Boosting Ultra‐Stable Lithium Batteries

Hierarchical Composite‐Solid‐Electrolyte with High Electrochemical Stability and Interfacial Regulation for Boosting Ultra‐Stable Lithium Batteries

New Cost‐Effective Halide Solid Electrolytes for All‐Solid‐State Batteries: Mechanochemically Prepared Fe3+‐Substituted Li2ZrCl6

Electrolyte/Electrode Interfaces in All-Solid-State Lithium Batteries: A Review

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New Cost‐Effective Halide Solid Electrolytes for All‐Solid‐State Batteries: Mechanochemically Prepared Fe³⁺‐Substituted Li₂ZrCl₆