Lithium superionic conduction in α-Li10P4N10: A promising inorganic solid electrolyte candidate

Chen, Fengjiao; Cheng, Sui Sun; Liu, Jianbo; Li, Shunning; Ouyang, Wenhong; Yuan, Kaijun; Liu, Baixin

doi:10.1016/j.jpowsour.2020.228744

Cited by 3 publications

(2 citation statements)

References 71 publications

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“…More importantly, owing to the operational flexibility of the electrospinning technique, incorporating nanoparticles into the electrospun nanofibers can be easily achieved by either direct incorporation during electrospinning or F I G U R E 2 (A) Reported total ionic conductivity of various inorganic SSEs at room temperature (RT). From top to bottom, data were taken from Yu et al [4][5][6][7][8][9] for argyrodite, Bernuy-Lopez et al [10][11][12][13][14][15][16] for garnet, Fang et al [17][18][19][20][21][22][23][24] for halide, Paik et al [25][26][27][28][29] for hydride, Kamaya et al [30][31][32][33][34] for LiSICON, Thokchom et al [35][36][37][38][39][40] for NaSICON, Chen et al [41][42][43][44] for nitride, Huang et al [45][46][47][48] for perovskite. (B) Comparison between the traditional organic electrolyte and different kinds of solid electrolyte...…”

Section: Introductionmentioning

confidence: 99%

“…(A) Reported total ionic conductivity of various inorganic SSEs at room temperature (RT). From top to bottom, data were taken from Yu et al 4–9 for argyrodite, Bernuy‐Lopez et al 10–16 for garnet, Fang et al 17–24 for halide, Paik et al 25–29 for hydride, Kamaya et al 30–34 for LiSICON, Thokchom et al 35–40 for NaSICON, Chen et al 41–44 for nitride, Huang et al 45–48 for perovskite. (B) Comparison between the traditional organic electrolyte and different kinds of solid electrolyte materials…”

Section: Introductionmentioning

confidence: 99%

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Progress and perspectives on electrospinning techniques for solid‐state lithium batteries

Lei

Tang

Shao³

2022

Carbon Energy

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Solid‐state electrolytes (SSEs), being the key component of solid‐state lithium batteries, have a significant impact on battery performance. Rational materials structure and composition engineering on SSEs are promising to improve their Li+ conductivity, interfacial contact, and mechanical integrity. Among the fabrication approaches, the electrospinning technique has attracted tremendous attention due to its own merits in constructing a three‐dimensional framework of SSEs with precise porosity structure, tunable materials composition, easy operation, and superior physicochemical properties. To this end, in this review, we provide a comprehensive summary of the recent development of electrospinning techniques for high‐performance SSEs. Firstly, we introduce the historical development of SSEs and summarize the fundamentals, including the Li+ transport mechanism and materials selection principle. Then, the versatility of electrospinning technologies in the construction of the three main types of SSEs and stabilization of lithium metal anodes is comprehensively discussed. Finally, a perspective on future research directions based on previous work is highlighted for developing high‐performance solid‐state lithium batteries based on electrospinning techniques.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Progress and perspectives on electrospinning techniques for solid‐state lithium batteries

Lei

Tang

Shao³

2022

Carbon Energy

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In situ formation of ionically conductive nanointerphase on Si particles for stable battery anode

Chen

Wang

et al. 2021

Sci. China Chem.

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Review of Multivalent Metal Ion Transport in Inorganic and Solid Polymer Electrolytes

O’Donnell

Greenbaum

2020

Batteries

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The lithium ion battery, with its high energy density and low reduction potential, continues to enchant researchers and dominate the landscape of energy storage systems development. However, the demands of technology in modern society have begun to reveal limitations of the lithium energy revolution. A combination of safety concerns, strained natural resources and geopolitics have inspired the search for alternative energy storage and delivery platforms. Traditional liquid electrolytes prove precarious in large scale schemes due to the propensity for leakage, the potential for side reactions and their corrosive nature. Alternative electrolytic materials in the form of solid inorganic ion conductors and solid polymer matrices offer new possibilities for all solid state batteries. In addition to the engineering of novel electrolyte materials, there is the opportunity to employ post-lithium chemistries. Utility of multivalent cation (Ca2+, Mg2+, Zn2+ and Al3+) transport promises a reduction in cost and increase in safety. In this review, we examine the current research focused on developing solid electrolytes using multivalent metal cation charge carriers and the outlook for their application in all solid state batteries.

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Lithium superionic conduction in α-Li10P4N10: A promising inorganic solid electrolyte candidate

Cited by 3 publications

References 71 publications

Progress and perspectives on electrospinning techniques for solid‐state lithium batteries

Progress and perspectives on electrospinning techniques for solid‐state lithium batteries

In situ formation of ionically conductive nanointerphase on Si particles for stable battery anode

Review of Multivalent Metal Ion Transport in Inorganic and Solid Polymer Electrolytes

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