Hierarchically Porous Graphene As a Lithium-air Battery Electrode

Overview

Journal Nano Lett

Publisher American Chemical Society

Specialty Biotechnology

Date 2011 Oct 12

PMID 21985448

Citations 46

Authors

Jie Xiao

Donghai Mei

Xiaolin Li

Wu Xu

Deyu Wang

Gordon L Graff

Wendy D Bennett

Zimin Nie

Laxmikant V Saraf

Ilhan A Aksay

Jun Liu

Ji-Guang Zhang

Affiliations

Soon will be listed here.

Abstract

The lithium-air battery is one of the most promising technologies among various electrochemical energy storage systems. We demonstrate that a novel air electrode consisting of an unusual hierarchical arrangement of functionalized graphene sheets (with no catalyst) delivers an exceptionally high capacity of 15000 mAh/g in lithium-O(2) batteries which is the highest value ever reported in this field. This excellent performance is attributed to the unique bimodal porous structure of the electrode which consists of microporous channels facilitating rapid O(2) diffusion while the highly connected nanoscale pores provide a high density of reactive sites for Li-O(2) reactions. Further, we show that the defects and functional groups on graphene favor the formation of isolated nanosized Li(2)O(2) particles and help prevent air blocking in the air electrode. The hierarchically ordered porous structure in bulk graphene enables its practical applications by promoting accessibility to most graphene sheets in this structure.

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