在环境空气中具有可逆长寿命的锂空气电池。

A reversible long-life lithium-air battery in ambient air.

机构信息

Energy Interface Technology Group, Energy Technology Research Institute, Energy Interface Technology Group, National Institute of Advanced Industrial Science and Technology, Umezono 1-1-1, Tsukuba 305-8568, Japan.

出版信息

Nat Commun. 2013;4:1817. doi: 10.1038/ncomms2855.

DOI:10.1038/ncomms2855

PMID:23652005

Abstract

Electrolyte degradation, Li dendrite formation and parasitic reactions with H₂O and CO₂ are all directly correlated to reversibility and cycleability of Li-air batteries when operated in ambient air. Here we replace easily decomposable liquid electrolytes with a solid Li-ion conductor, which acts as both a catholyte and a Li protector. Meanwhile, the conventional solid air cathodes are replaced with a gel cathode, which contacts directly with the solid catholyte to form a closed and sustainable gel/solid interface. The proposed Li-air cell has sustained repeated cycling in ambient air for 100 cycles (~78 days), with discharge capacity of 2,000 mAh g(-1). The recharging is based largely on the reversible reactions of Li₂CO₃ product, originating from the initial discharge product of Li₂O₂ instead of electrolyte degradation. Our results demonstrate that a reversible long-life Li-air battery is attainable by coordinated approaches towards the focal issues of electrolytes and Li metal.

摘要

当在空气中运行时，电解质的降解、锂枝晶的形成以及与 H₂O 和 CO₂ 的寄生反应都与锂空气电池的可逆性和循环能力直接相关。在这里，我们用固体锂离子导体代替了容易分解的液体电解质，该导体既充当阴极，又充当锂保护剂。同时，用凝胶阴极取代了传统的固体空气阴极，该阴极直接与固体阴极接触，形成封闭的、可持续的凝胶/固体界面。所提出的锂空气电池在空气中持续循环 100 次（~78 天），放电容量为 2000 mAh g(-1)。充电主要基于 Li₂CO₃产物的可逆反应，该产物来自 Li₂O₂的初始放电产物，而不是电解质的降解。我们的结果表明，通过协调解决电解质和锂金属的焦点问题，可以实现具有可逆长寿命的锂空气电池。

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在环境空气中具有可逆长寿命的锂空气电池。

A reversible long-life lithium-air battery in ambient air.

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