The synergetic effect of lithium polysulfide and lithium nitrate to prevent lithium dendrite growth

Li, Weiyang; Yao, Hong‐Bin; Yan, Kai; Zheng, Guangyuan; Liang, Zheng; Chiang, Yet‐Ming; Cui, Yi

doi:10.1038/ncomms8436

Cited by 1,299 publications

(961 citation statements)

References 41 publications

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“…Free‐standing graphene foam provides several promising features as underneath layer for Li anode, including (1) relative larger surface area than 2D substrates to lower the real specific surface current density and the possibility of dendrite growth, (2) interconnected framework to support and recycle dead Li, and (3) good flexibility to sustain the volume fluctuation during repeated incorporation/extraction of Li. The synergy between the LiNO 3 and polysulfides provides the feasibility to the formation of robust SEI in an ether‐based electrolyte 176, 177. The efficient in situ formed SEI‐coated graphene structure allows stable Li metal anode with the cycling Coulombic efficiency of ≈97% with high safety and efficiency performance, which is with a low resistance of 19.65 Ω (29.10 Ω for Cu foil based Li metal anode) and high ion conductivity of 5.42 × 10 −2 mS cm −1 (2.33 × 10 −2 mS cm −1 for Cu foil based Li metal anode).…”

Section: Sei Regulationmentioning

confidence: 99%

A Review of Solid Electrolyte Interphases on Lithium Metal Anode

et al. 2015

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Lithium metal batteries (LMBs) are among the most promising candidates of high‐energy‐density devices for advanced energy storage. However, the growth of dendrites greatly hinders the practical applications of LMBs in portable electronics and electric vehicles. Constructing stable and efficient solid electrolyte interphase (SEI) is among the most effective strategies to inhibit the dendrite growth and thus to achieve a superior cycling performance. In this review, the mechanisms of SEI formation and models of SEI structure are briefly summarized. The analysis methods to probe the surface chemistry, surface morphology, electrochemical property, dynamic characteristics of SEI layer are emphasized. The critical factors affecting the SEI formation, such as electrolyte component, temperature, current density, are comprehensively debated. The efficient methods to modify SEI layer with the introduction of new electrolyte system and additives, ex‐situ‐formed protective layer, as well as electrode design, are summarized. Although these works afford new insights into SEI research, robust and precise routes for SEI modification with well‐designed structure, as well as understanding of the connection between structure and electrochemical performance, is still inadequate. A multidisciplinary approach is highly required to enable the formation of robust SEI for highly efficient energy storage systems.

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Section: Sei Regulationmentioning

confidence: 99%

A Review of Solid Electrolyte Interphases on Lithium Metal Anode

et al. 2015

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confidence: 99%

“…For the Li metal anode in liquid electrolyte, the COR (286.6 eV)38, 39 and COOR (288.8 eV)38, 39 groups (Figure 5a) emerge during the SEI formation. After cycling, there are a lot of CO 3 2− (289.5 eV)36, 40 and CF 3 (293.1 eV)38, 39 groups (Figure 5c) on the surface of Li metal anode because of the decomposition of carbonate solvents and Li salt anions. Seen from the F 1s spectra (Figure 5b), the LiF (684.9 eV) and Li x PO y F z (687.4 eV)41, 42 can be observed during the SEI formation, which are the decomposition products of Li salt anions.…”

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confidence: 99%

“…Seen from the F 1s spectra (Figure 5b), the LiF (684.9 eV) and Li x PO y F z (687.4 eV)41, 42 can be observed during the SEI formation, which are the decomposition products of Li salt anions. After cycling, the amount of LiF and Li x PO y F z change significantly and a lot of CF 3 (689.1 eV) groups emerge (Figure 5d), indicating the decomposition of LiTFSI and LiPF 6 during the cycling 38, 43. Consequently, in the LMB using liquid electrolyte, the reduction products of electrolyte markedly increase in the SEI layer after cycling, elucidating the SEI layer is too fragile to protect Li metal anode.…”

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confidence: 99%

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A Dual‐Salt Gel Polymer Electrolyte with 3D Cross‐Linked Polymer Network for Dendrite‐Free Lithium Metal Batteries

et al. 2018

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Lithium metal batteries show great potential in energy storage because of their high energy density. Nevertheless, building a stable solid electrolyte interphase (SEI) and restraining the dendrite growth are difficult to realize with traditional liquid electrolytes. Solid and gel electrolytes are considered promising candidates to restrain the dendrites growth, while they are still limited by low ionic conductivity and incompatible interphases. Herein, a dual‐salt (LiTFSI‐LiPF6) gel polymer electrolyte (GPE) with 3D cross‐linked polymer network is designed to address these issues. By introducing a dual salt in 3D structure fabricated using an in situ polymerization method, the 3D‐GPE exhibits a high ionic conductivity (0.56 mS cm−1 at room temperature) and builds a robust and conductive SEI on the lithium metal surface. Consequently, the Li metal batteries using 3D‐GPE can markedly reduce the dendrite growth and achieve 87.93% capacity retention after cycling for 300 cycles. This work demonstrates a promising method to design electrolytes for lithium metal batteries.

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“…However, these strategies cannot change the breakage/repair mechanism of SEI layer, and significantly improve the Coulombic efficiency of Li plating/stripping. In addition, optimization of electrolyte using additives,8 high concentrated electrolytes,9 and ionic liquid electrolytes10 can enhance the stability of SEI layers, and can improve the Coulombic efficiency of Li plating/stripping. However, the electrolyte additives are consumed during the SEI formation and thus affect the electrochemical performance.…”

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confidence: 99%

Passivation of Lithium Metal Anode via Hybrid Ionic Liquid Electrolyte toward Stable Li Plating/Stripping

et al. 2016

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Hybrid electrolyte of ionic liquid and ethers is used to passivate the surface of Li metal surface via modification of the as‐formed solid electrolyte interphase with N‐propyl‐N‐methylpyrrolidinium bis(trifluoromethanesulfonyl)amide (Py13TFSI), thereby reducing the side reactions between the Li metal and electrolyte, leading to remarkably suppressed Li dendrite growth and mitigating Li metal corrosion.

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The synergetic effect of lithium polysulfide and lithium nitrate to prevent lithium dendrite growth

Cited by 1,299 publications

References 41 publications

A Review of Solid Electrolyte Interphases on Lithium Metal Anode

A Review of Solid Electrolyte Interphases on Lithium Metal Anode

A Dual‐Salt Gel Polymer Electrolyte with 3D Cross‐Linked Polymer Network for Dendrite‐Free Lithium Metal Batteries

Passivation of Lithium Metal Anode via Hybrid Ionic Liquid Electrolyte toward Stable Li Plating/Stripping

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