A Flexible Electron-blocking Interfacial Shield for Dendrite-free Solid Lithium Metal Batteries

Huo, Hanyu; Gao, Jian; Zhao, Ning; Zhang, Dongxing; Holmes, Nathaniel; Li, Xiaona; Sun, Yipeng; Fu, Jiamin; Li, Ruying; Guo, Xiangxin; Sun, Xueliang

doi:10.21203/rs.3.rs-41233/v1

Cited by 7 publications

(9 citation statements)

References 40 publications

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“…For reference, the result for the bare LLZTO cell is also provided in the Supplementary Materials (fig. S5), which recorded the CCD value of 0.3 mA cm −2 , consistent with previous reports (48). Our results show that the short circuit of the Ag-coated LLZTO cell occurs at a current density of 1.5 mA cm −2 upon increasing the current up to 3.2 mA cm −2 with a step of 0.1 mA cm −2 (Fig.…”

Section: Enhanced Electrochemical Performance From the Layer-by-layer...supporting

confidence: 92%

“…For reference, we plotted the relative performance standing of our hybrid full cell in comparison with those of recently reported relevant solid-state cells that have gone through various interfacial modifications (e.g., the introduction of interlayers or removal of interfacial impurities as denoted in the figure) with respect to two key demonstrated indicators of current density and long-term cycling in Fig. 5G ( 17 , 18 , 20 – 25 , 48 , 50 – 55 ) It clearly manifests that the modification with the Ag/LiF multilayer in the current work excels the previous reports, not only in the high-rate capability (2 C cathode ) but also in the long-cycle durability (over 3000 cycles). It is our belief that it is attributed to the orthogonal multifunctions of the Ag/LiF layer, which has enabled the homogeneous interfacial property during charge/discharge and allowed the operation of the lithium cell even at high current density by preventing the electronic leakage through the cell.…”

Section: Resultsmentioning

confidence: 99%

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Design of a lithiophilic and electron-blocking interlayer for dendrite-free lithium-metal solid-state batteries

Lee

Kim

et al. 2022

Sci. Adv.

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All-solid-state batteries are a potential game changer in the energy storage market; however, their practical employment has been hampered by premature short circuits caused by the lithium dendritic growth through the solid electrolyte. Here, we demonstrate that a rational layer-by-layer strategy using a lithiophilic and electron-blocking multilayer can substantially enhance the performance/stability of the system by effectively blocking the electron leakage and maintaining low electronic conductivity even at high temperature (60°C) or under high electric field (3 V) while sustaining low interfacial resistance (13.4 ohm cm 2 ). It subsequently results in a homogeneous lithium plating/stripping, thereby aiding in achieving one of the highest critical current densities (~3.1 mA cm −2 ) at 60°C in a symmetric cell. A full cell paired with a commercial-level cathode exhibits exceptionally long durability (>3000 cycles) and coulombic efficiency (99.96%) at a high current density (2 C; ~1.0 mA cm −2 ), which records the highest performance among all-solid-state lithium metal batteries reported to date.

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Section: Enhanced Electrochemical Performance From the Layer-by-layer...supporting

confidence: 92%

Section: Resultsmentioning

confidence: 99%

Design of a lithiophilic and electron-blocking interlayer for dendrite-free lithium-metal solid-state batteries

Lee

Kim

et al. 2022

Sci. Adv.

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“…To improve the interfacial contact and kinetics, various artificial interlayers with better wettability for metallic Li are introduced. Li et al introduced subtle carbon to react with Li 2 CO 3 on the garnet SSEs in Ar at 700 °C and significantly reduced the interfacial resistances to 28 Ω•cm 2 ( Figure 7(a)) [98] . Apart from improving interfacial contact, the interlayer can facilitate the ion-conducting at the interface and block the electron infusion.…”

Section: Optimized Solid-solid Interfacial Stabilitymentioning

confidence: 99%

The interfacial engineering of metal electrodes for high-specific-energy and long-lifespan batteries

Shen

Zhang

et al. 2022

iEnergy

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High-specific-energy batteries with long-lifespan are the development aspiration for energy storage applications. Metal electrodes with high specific capacity and low reduction potential are potential candidates for next-generation high-specific-energy batteries. Nevertheless, the stability of the metal electrode batteries is constantly suffered from the unstable interface issue during the plating/stripping process, such as dendrite formation, dynamic evolution of solid electrolyte interphase, and other accompanied side reactions. To solve these challenges, numerous researches have been intensively studied based on the interfacial engineering of metal electrodes, including electrode configuration optimization, interfacial chemistry regulation and solid-solid interface construction, and the recent progress is elaborately introduced in this paper. Nevertheless, the dendrite issues cannot be entirely prohibited in solid metal electrodes, which motivate the search for potential alternatives. Liquid-metal electrodes with completely reversible structural changes and high mass transfer rate are rendered as an effective approach to solve the dendrite problem. Therefore, the development of liquid metal electrode batteries is reviewed in this paper, in which the interfacial issues are explicated and some commendable achievements are summarized. In the end, the implementation of interfacial engineering and the development roadmap of the metal electrode batteries are prospected.

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“…ICEs show higher room-temperature ionic conductivity (10 −4 ~10 −2 S cm −1 ), [17] wide electrochemical windows, and excellent mechanical robustness, but poor interfacial contacts or unsatisfactory stability hinder their widespread use. [20,21] Furthermore, the thickness of higher density ICEs is difficult to be reduced, [22] which is not conducive to increasing the energy density at the cell level. As the complex of SPEs and ICEs, CSEs, which inherit the flexibility from SPEs and high mechanical modulus from ICEs, have been considered the promising SSEs for ASSLMBs with excellent comprehensive performances.…”

Section: Introductionmentioning

confidence: 99%

Scalable, thin asymmetric composite solid electrolyte for high‐performance all‐solid‐state lithium metal batteries

Wang

Liang

Liu

et al. 2022

Interdisciplinary Materials

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All-solid-state Li metal batteries (ASSLMBs) have been considered the most promising candidates for next-generation energy storage devices owing to their high-energy density and safety. However, some obstacles such as thick solid electrolyte (SSEs) and unstable interface between the solid-state electrolytes (SSEs) and the electrodes have restricted the practical application of ASSLBs. Here, the scalable polyimide (PI) film reinforced asymmetric ultrathin (~20 μm) composite solid electrolyte (AU-CSE) with a ceramic-rich layer and polymer-rich layer is fabricated by a both-side casting method and rolling process. The ceramic-rich layer not only acts as a "securer" to inhibit the lithium dendrite growth but also redistributes Li-ions uniform deposition, while the polymer-rich layer improves the compatibility with cathode materials. As a result, the obtained AU-CSE demonstrates an ionic conductivity of 1.44 × 10 −4 S cm −1 at 35°C. The PI-reinforced AU-CSE enables

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A Flexible Electron-blocking Interfacial Shield for Dendrite-free Solid Lithium Metal Batteries

Cited by 7 publications

References 40 publications

Design of a lithiophilic and electron-blocking interlayer for dendrite-free lithium-metal solid-state batteries

Design of a lithiophilic and electron-blocking interlayer for dendrite-free lithium-metal solid-state batteries

The interfacial engineering of metal electrodes for high-specific-energy and long-lifespan batteries

Scalable, thin asymmetric composite solid electrolyte for high‐performance all‐solid‐state lithium metal batteries

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