Stabilizing Polymer–Lithium Interface in a Rechargeable Solid Battery

Yan, Min; Liang, Jun‐Hong; Zuo, Tong‐Tong; Yin, Ya‐Xia; Xin, Sen; Tan, Shuang‐Jie; Guo, Yu‐Guo; Li, Wan

doi:10.1002/adfm.201908047

Cited by 70 publications

(61 citation statements)

References 37 publications

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“…Therefore, various interfacial engineering methods have been explored, mainly focusing on high electronic conducting, mixed ionic-electronic conducting and ionic conducting but electronic insulating interlayers. Recently, coating metals, such as Si [78] , Mg [20] , Al [23,79] and Ge [19] , or metal oxides, like Al 2 O 3 [19] and ZnO [22] , can trigger an alloying reaction with Li and form high electronic conducting Li-metal alloy interlayers. Li-metal alloy interlayers exhibit excellent lithiophilicity with Li and significantly improve the physical contact, leading to an even current distribution and low interfacial resistance [Figure 4C].…”

Section: Surface Energy and Chemical Interactionsmentioning

confidence: 99%

Modulating the lithiophilicity at electrode/electrolyte interface for high-energy Li-metal batteries

Li¹,

Zhang²,

Zhu³

et al. 2022

Energy Mater

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Lithium-metal anodes show significant promise for the construction of high-energy rechargeable batteries due to their high theoretical capacity (3860 mAh g -1 ) and low redox potential (-3.04 V vs. a standard hydrogen electrode). When Li metal is used with conventional liquid and solid electrolytes, the poor lithiophilicity of the electrolyte results in an unfavorable parasitic reaction and uneven distribution of Li + flux at the electrode/electrolyte interface. These issues result in limited cycle life and dendrite problems associated with the Li-metal anode that can lead to rapid performance fade, failure and even safety risks of the battery. The lithiophilicity at the anode/electrolyte interface is important for the stable and safe operation of rechargeable Li-metal batteries. In this review, several factors that affect the lithiophilicity of electrolytes are discussed, including surface energy, roughness and chemical interactions. The existing problems and the strategies for improving the lithiophilicity of different electrolytes are also discussed. This review helps to shed light on the understanding of interfacial chemistry vs. Li metal of various electrolytes and guide interfacial engineering towards the practical realization of high-energy

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Section: Surface Energy and Chemical Interactionsmentioning

confidence: 99%

Modulating the lithiophilicity at electrode/electrolyte interface for high-energy Li-metal batteries

Li¹,

Zhang²,

Zhu³

et al. 2022

Energy Mater

Self Cite

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“…Similarly, AFM in PeakForce Tunnelling mode showed that an intermediary Mg 3 N 2 layer between Li metal anode and PEO SSE enabled a smoother, more robust surface with a more homogeneous current distribution on the Li anode surface (Figure 13c–f). [ 288 ] This facilitated homogeneous Li plating/stripping and promoted fast Li ion kinetics.…”

Section: Ec‐afm For the Understanding Of Libs And Their Materialsmentioning

confidence: 99%

“…Reproduced with permission. [ 288 ] Copyright 2020, Wiley‐VCH. AFM images of the surface of g) silver and h) gold interlayers at various charge/discharge states: pristine, after 0.2 mA cm −2 galvanostatic deposition for 15 and 150 min, and 0.1 mA cm −2 galvanostatic stripping of lithium.…”

Section: Ec‐afm For the Understanding Of Libs And Their Materialsmentioning

confidence: 99%

Characterizing Batteries by In Situ Electrochemical Atomic Force Microscopy: A Critical Review

Zhang

Said

Smith

et al. 2021

Advanced Energy Materials

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Although lithium, and other alkali ion, batteries are widely utilized and studied, many of the chemical and mechanical processes that underpin the materials within, and drive their degradation/failure, are not fully understood. Hence, to enhance the understanding of these processes various ex situ, in situ and operando characterization methods are being explored. Recently, electrochemical atomic force microscopy (EC‐AFM), and related techniques, have emerged as crucial platforms for the versatile characterization of battery material surfaces. They have revealed insights into the morphological, mechanical, chemical, and physical properties of battery materials when they evolve under electrochemical control. This critical review will appraise the progress made in the understanding batteries using EC‐AFM, covering both traditional and new electrode–electrolyte material junctions. This progress will be juxtaposed against the ability, or inability, of the system adopted to embody a truly representative battery environment. By contrasting key EC‐AFM literature with conclusions drawn from alternative characterization tools, the unique power of EC‐AFM to elucidate processes at battery interfaces is highlighted. Simultaneously opportunities for complementing EC‐AFM data with a range of spectroscopic, microscopic, and diffraction techniques to overcome its limitations are described, thus facilitating improved battery performance.

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“…[ 35 ] These modification schemes provide new concepts to modify Li metal anodes, and the combination of fast Li + conductor modification layer and alloy modification layer may show advantages to suppress Li dendrites. [ 36–39 ] As previous reported, electronic or Li + conductors were chosen as artificial SEI for lithium anode, such as LiAl, [ 40 ] LiPb, [ 41 ] LiSn, [ 42 ] LiZn, [ 43 ] Li 2 S, [ 44,45 ] Li 3 PS 4 , and [ 46 ] Li 3 N. [ 47–50 ] Recently, a novel artificial SEI modification method has been developed with dual‐conductive artificial layer for lithium anode, such as LiF/AlLi, [ 51 ] LiF/Cu, [ 52,53 ] Li 3 N/LiMg, [ 54 ] Cu/Li 3 N, [ 55 ] and LiCl/LiIn/LiZn/LiBi/LiAs. [ 56 ] For example, Yan [ 57 ] achieved remarkable results in inhibiting lithium dendrite with LiNO 3 as the ionic‐conductive additive.…”

Section: Introductionmentioning

confidence: 99%

In Situ‐Formed Dual‐Conductive Protecting Layer for Dendrite‐Free Li Metal Anodes in All‐Solid‐State Batteries

et al. 2021

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Lithium metal anode is regarded as one of the most promising electrode materials for high energy‐rechargeable batteries. Nevertheless, the utilization of lithium metal anode suffers from the detrimental lithium dendrite growth caused by uneven lithium deposition. Herein, a dual‐conductive protecting layer is formed in situ on a lithium metal surface as an artificial solid electrolyte interface, which is composed of electronic‐conductive lithiophilic lithium–gallium alloy and lithium‐ion‐conductive lithium nitride. The protective layer can not only ensure uniform lithium‐ion diffusion but also act as a nuclear agent to lower the deposition overpotential. With this artificial solid–electrolyte interface, the dendrite growth of lithium is significantly suppressed. Symmetric half cells and full cells with a modified lithium metal anode exhibit significantly improved electrochemical performance compared with the bare lithium metal anode.

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Stabilizing Polymer–Lithium Interface in a Rechargeable Solid Battery

Cited by 70 publications

References 37 publications

Modulating the lithiophilicity at electrode/electrolyte interface for high-energy Li-metal batteries

Modulating the lithiophilicity at electrode/electrolyte interface for high-energy Li-metal batteries

Characterizing Batteries by In Situ Electrochemical Atomic Force Microscopy: A Critical Review

In Situ‐Formed Dual‐Conductive Protecting Layer for Dendrite‐Free Li Metal Anodes in All‐Solid‐State Batteries

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