一种用于锂氧电池中实现锂金属负极高利用率的无枝晶锂电镀主体材料。

A dendrite-free Li plating host towards high utilization of Li metal anode in Li-O battery.

作者信息

Li Chao, Wei Jishi, Li Panlong, Tang Wenfei, Feng Wuliang, Liu Jingyuan, Wang Yonggang, Xia Yongyao

机构信息

Department of Chemistry and Shanghai Key Laboratory of Molecular Catalysis and Innovative Materials, Institute of New Energy, iChEM (Collaborative Innovation Center of Chemistry for Energy Materials), Fudan University, Shanghai 200433, China.

出版信息

Sci Bull (Beijing). 2019 Apr 15;64(7):478-484. doi: 10.1016/j.scib.2019.03.004. Epub 2019 Mar 6.

DOI:10.1016/j.scib.2019.03.004

PMID:36659799

Abstract

The intense interest of Li-O battery stems from its ultrahigh theoretical energy density, but its application is still hindered by the issues of Li anode. Herein, RuO-CNTs composite, a conventional O cathode catalyst in Li-O battery, is first utilized as an anode host for dendrite-free Li plating/stripping with high Coulombic efficiency. It is demonstrated that such excellent plating/stripping performance arises from the lithiophilicity characteristic of Ru nanoparticles (that is derived from the in-situ electrochemical conversion from RuO to Ru/LiO) and buffer space provided by CNTs. Furthermore, the RuO-CNTs electrode pre-deposited with limited Li (RuO-CNTs@Li anode) is coupled with a RuO-CNTs catalytic cathode to form a Li-O full cell, which displays an extended cycle life with dramatically improved energy density. The achieved cell shows a high stability of 200 cycles with RuO-CNTs@Li anode (1 mg Li) that sheds light on the efficient utilization of Li anode in Li-O batteries.

摘要

锂氧电池的巨大吸引力源于其超高的理论能量密度，但其应用仍受到锂负极问题的阻碍。在此，作为锂氧电池中传统的氧阴极催化剂的RuO-CNTs复合材料，首次被用作阳极主体，用于实现无枝晶锂的高效库仑效率的电镀/剥离。结果表明，这种优异的电镀/剥离性能源于Ru纳米颗粒的亲锂特性（这是由RuO原位电化学转化为Ru/LiO所产生的）以及碳纳米管提供的缓冲空间。此外，预沉积有限锂的RuO-CNTs电极（RuO-CNTs@Li阳极）与RuO-CNTs催化阴极耦合形成锂氧全电池，该全电池显示出延长的循环寿命以及显著提高的能量密度。所制备的电池在使用RuO-CNTs@Li阳极（1毫克锂）时表现出200次循环的高稳定性，这为锂氧电池中锂负极的高效利用提供了思路。

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一种用于锂氧电池中实现锂金属负极高利用率的无枝晶锂电镀主体材料。

A dendrite-free Li plating host towards high utilization of Li metal anode in Li-O battery.

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