Ultra-fine surface solid-state electrolytes for long cycle life all-solid-state lithium-air batteries

Wang Sheng; Wang Jue; Liu Jingjing; Song Hucheng; Liu Yijie; Wang Pengfei; He Ping; Xu Jun; Zhou Haoshen

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Ultra-fine surface solid-state electrolytes for long cycle life all-solid-state lithium-air batteries

机译：超细表面固态电解质，用于长循环寿命全固态锂气电池

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Solid-state electrolytes (SSEs) are potential candidates for developing high-energy-density and safe all-solid-state lithium (Li)-metal batteries due to the elimination of most of the safety issues encountered with liquid electrolytes. However, unfortunately, dangerous Li dendrites still form in SSEs. Herein, we report a simple nano-polishing method to prepare a high-performance all-solid-sate Li-air battery that consists of an air cathode, Li metal anode and ultra-fine surface Li1.5Al0.5Ge1.5P3O12 (LAGP) electrolyte. Such a design effectively reduces the interface impedance of the battery and meanwhile creates an ultra-smooth/flat interface between the Li metal and LAGP electrolyte that can produce a uniform electric field across the interface, thus enabling a homogeneous metal Li-forming/deforming environment during discharge/charge processes. As a result, a long cycle life all-solid-state Li-air battery has been obtained at room temperature at 400 mA g(-1) with a capacity limitation of 1000 mA h g(-1). The experimental results reveal that Li dendrites are suppressed through eliminating protrusion-induced locally concentrated free electron density on the surface of Li metal. The present ultra-fine interface engineering may be robust enough to suppress Li-dendrites, providing new insights into the interface between the Li-metal and SSE to develop future all solid-state Li-metal batteries.

机译：固态电解质（SSES）是用于开发高能密度和安全的全固态锂（LI） - 金属电池的潜在候选者，由于消除液体电解质遇到的大多数安全问题。然而，不幸的是，危险的Li Dendrites仍然在SSE中形成。在此，我们报告了一种简单的纳米抛光方法，制备包括空气阴极，Li金属阳极和超细表面Li1.5Al0.5Ge1.5P3O12（LAGP）的高性能全固态锂气体电池电解质。这种设计有效地降低了电池的界面阻抗，并且同时在Li金属和LAGP电解质之间产生超光滑/平坦的界面，可以在界面上产生均匀的电场，从而能够实现均匀的金属Li成形/变形环境在放电/充电过程中。结果，在室温下在400mA g（-1）的室温下获得了长循环寿命全固态Li-空气电池，其容量限制为1000mA H g（-1）。实验结果表明，通过消除Li金属表面的突出型局部浓缩的自由电子密度来抑制Li树枝状体。本发明的超细界面工程可能足够强大，以抑制Li-Dendrites，为Li-Metal和SSE之间的界面提供新的见解，以开发未来的所有固态Li金电池。

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来源
《Journal of Materials Chemistry, A. Materials for energy and sustainability 》 |2018年第43期| 共7页
作者
Wang Sheng; Wang Jue; Liu Jingjing; Song Hucheng; Liu Yijie; Wang Pengfei; He Ping; Xu Jun; Zhou Haoshen;
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作者单位

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Sch Elect Sci &

Engn Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Sch Elect Sci &

Engn Nanjing 210093 Jiangsu Peoples R China;

Nanjing Univ Collaborat Innovat Ctr Adv Microstruct Natl Lab Solid State Microstruct Coll Engn &

Appl Sci Ctr Energy Storage Mat &

Tec Nanjing 210093 Jiangsu Peoples R China;

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中图分类工程材料学 ;
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1. Ultra-fine surface solid-state electrolytes for long cycle life all-solid-state lithium-air batteries [J] . Wang Sheng, Wang Jue, Liu Jingjing, Journal of Materials Chemistry, A. Materials for energy and sustainability . 2018 ,第43期

机译：超细表面固态电解质，用于长循环寿命全固态锂气电池
2. A Solid-State, Rechargeable, Long Cycle Life Lithium-Air Battery [J] . THE ELECTROCHEMICAL SOCIETY INTERFACE GROUP The Electrochemical Society interface . 2010 ,第2期

机译：固态可充电长寿命锂空气电池
3. Prolonging the Cycle Life of a Lithium-Air Battery by Alleviating Electrolyte Degradation with a Ceramic-Carbon Composite Cathode [J] . Luo Zhifu, Li Yanyan, Liu Zixuan, ChemSusChem . 2019 ,第22期

机译：通过减轻陶瓷 - 碳复合阴极的电解质降解延长锂空气电池的循环寿命
4. A NEW BATTERY ACTIVATOR: ULTRA-FINE CARBON ORGANIC COLLOID FOR LEAD-ACID BATTERIES TO EXTEND THE CYCLE LIFE 2 TO 3 TIMES [C] . Atsushi Sato, Akiya Kozawa Batteries for portable applications and electric vehicles . 1997

机译：一种新的电池活化剂：用于铅酸电池的超细碳有机胶体，可将循环寿命延长2至3倍
5. Advanced cathodes and electrolytes for lithium-ion and lithium-air batteries [D] . Allen, Christopher John. 2012

机译：锂离子和锂空气电池的高级阴极和电解质
6. Ionic Conductivity and Cycling Stability Improvement of PVDF/Nano-Clay Using PVP as Polymer Electrolyte Membranes for LiFePO4 Batteries [O] . Endah R. Dyartanti, Agus Purwanto, I. Nyoman Widiasa, 2018

机译：使用PVP作为LiFePO4电池的聚合物电解质膜的PVDF /纳米粘土的离子电导率和循环稳定性的改善
7. A Long Cycle Life, All-Solid-State Lithium Battery with a CeramicPolymer Composite Electrolyte [O] . -1

机译：具有陶瓷聚合物复合电解质的长循环寿命，全固态锂电池
8. Solid-State, Rechargeable, Long Cycle Life Lithium-Air Battery (Postprint) [R] . Kumar, B., Kumar, J., Leese, R., 2010

机译：固态，可充电，长循环寿命锂空气电池（后印刷）

Ultra-fine surface solid-state electrolytes for long cycle life all-solid-state lithium-air batteries

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