Two-Dimensional Phosphorene-Derived Protective Layers on a Lithium Metal Anode for Lithium-Oxygen Batteries

Kim, Young‐Jin; Koo, Dongho; Ha, Sangtae; Jung, Sung Chul; Yim, Taeeun; Kim, Hanseul; Oh, Seung Kyo; Kim, Dong-Min; Choi, An-Seop; Kang, Yongku; Ryu, Kyoung Han; Jang, Moongyu; Han, Young‐Kyu; Lee, Kyu‐Tae

doi:10.1021/acsnano.8b00348

Cited by 119 publications

(87 citation statements)

References 76 publications

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“…Lee et al. conducted ex‐situ NMR on cycled Li‐metal anode in an DMA electrolyte under two different protective conditions and provided valuable information about the decomposition of the electrolyte, Figure d . Obviously, NMR/MRI are outstanding techniques which can provide both morphology and chemical composition information.…”

Section: Characterization Of Li−metal Anodesmentioning

confidence: 99%

Safe Lithium‐Metal Anodes for Li−O₂ Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Hong

Zhao

Xiao

et al. 2019

Batteries & Supercaps

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Rechargeable LiÀ O 2 batteries play an increasing important role as energy storage devices, which have both, a high capacity anode and a cathode using an inexhaustible resource. As a key component in LiÀ O 2 batteries, the Li-metal anode suffers from major drawbacks related to Li dendrite formation and SEI layer growth, which are also major issues for Li-metal rechargeable batteries. This review presents an overview on the scientific challenges, fundamental mechanisms and modification strategies of Li-metal anodes for LiÀ O 2 batteries. Firstly, basic principles and challenges on Li-metal anodes are briefly retrospected. We further summarize and categorize the prevailing characterization techniques based on Li dendrite morphology characterization and SEI composition analysis. The up-to-date development of in-situ and operando characterization is also included. Following the obtained insights, effective protection/modification strategies towards practical application for LiÀ O 2 batteries are presented. Furthermore, we highlight the significance of advanced characterization techniques in interrogating the buried keys for solving practical hindrances for LiÀ O 2 batteries. The comprehensive characterization and analysis of Li anodes, cathodes, and electrolytes by various methods together with the development of novel techniques are expected to be indispensable to gain a thorough understanding of the battery operation and for offering guidelines for their practical development.

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Section: Characterization Of Li−metal Anodesmentioning

confidence: 99%

Safe Lithium‐Metal Anodes for Li−O₂ Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Hong

Zhao

Xiao

et al. 2019

Batteries & Supercaps

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“…The high ionic conductivity of Li 2 S relieved non-uniform Li ions flux and suppressed Li dendrites, but it is almost an insulator. Kim et al proposed a method that phosphorene is added dropwise on the Li foil surface (Kim et al, 2018). The phosphorene layer located above the Li surface spontaneously reacts with Li to form Li 3 P. The phosphorene-coated Li metal electrode displayed a constant capacity of 1,000 mAh g −1 with no capacity reduction even after 50 cycles for the Li-O 2 battery.…”

Section: Introductionmentioning

confidence: 99%

Lithiophilic Silver Coating on Lithium Metal Surface for Inhibiting Lithium Dendrites

Zuo

Zhuang

et al. 2020

Front. Chem.

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Li metal batteries (LMBs) are known as the ideal energy storage candidates for the future rechargeable batteries due to the high energy density. However, uncontrolled Li dendrites growing during charge/discharge process causes extremely low coulombic efficiency and short lifespan. In this work, a thin lithiophilic layer of Ag was coated on the bare Li surface via a thermal evaporation method, which alleviated volume variations and suppressed Li dendrites growth during cycling. As a result, a long lifespan of 250 h at a current density of 1 mA cm −2 was achieved in the symmetric cell when using the Ag-modified Li foil (Ag@Li). The LiFePO 4 |Li full cell demonstrated an excellent cycling performance with a high specific capacity of 131 mAh g −1 even after 300 cycles at 0.5 C. This study offers a suitable method for stabilizing Li metal anodes in LMBs.

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“…Va rious strategies have been developed to stabilize Li metal anodes.O ne is an alloying strategy,which replaces Li metal with Li alloys,such as Li-Al, Li-Si, and Li-Sn alloys. [9] Very recently,areally convenient method has been presented. By contrast, forming ap rotective layer on Li metal anodes could prevent the direct interaction with electrolytes without capacity loss.L ee and co-workers reported ac omposite protective layer comprising Al 2 O 3 and polyvinylidene fluoride-hexafluoro propylene for Li metal anodes,w hich resulted in dramatic enhancement of cycling stability of Li-O 2 batteries.…”

mentioning

confidence: 99%

An Extremely Simple Method for Protecting Lithium Anodes in Li‐O₂ Batteries

Zhang

Wang

et al. 2018

Angew Chem Int Ed

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Rechargeable Li-O batteries have aroused much attention for their high energy density as a promising battery technology; however, the performance of the batteries is still unsatisfactory. Lithium anodes, as one of the most important part of Li-O batteries, play a vital role in improving the cycle life of the batteries. Now, a very simple method is introduced to produce a protective film on lithium surface via chemical reactions between lithium metals and 1,4-dioxacyclohexane. The film is mainly composed of ethylene oxide monomers and endows Li-O batteries with enhanced cycling stability. The film could effectually reduce the morphology changes and suppress the parasitic reactions of lithium anodes. This simple approach provides a new strategy to protect lithium anodes in Li-O batteries.

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Two-Dimensional Phosphorene-Derived Protective Layers on a Lithium Metal Anode for Lithium-Oxygen Batteries

Cited by 119 publications

References 76 publications

Safe Lithium‐Metal Anodes for Li−O₂ Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Safe Lithium‐Metal Anodes for Li−O₂ Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Lithiophilic Silver Coating on Lithium Metal Surface for Inhibiting Lithium Dendrites

An Extremely Simple Method for Protecting Lithium Anodes in Li‐O₂ Batteries

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Two-Dimensional Phosphorene-Derived Protective Layers on a Lithium Metal Anode for Lithium-Oxygen Batteries

Cited by 119 publications

References 76 publications

Safe Lithium‐Metal Anodes for Li−O2 Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Safe Lithium‐Metal Anodes for Li−O2 Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Lithiophilic Silver Coating on Lithium Metal Surface for Inhibiting Lithium Dendrites

An Extremely Simple Method for Protecting Lithium Anodes in Li‐O2 Batteries

Contact Info

Product

Resources

About

Safe Lithium‐Metal Anodes for Li−O₂ Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Safe Lithium‐Metal Anodes for Li−O₂ Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

An Extremely Simple Method for Protecting Lithium Anodes in Li‐O₂ Batteries