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Graphene-modified nanostructured vanadium pentoxide hybrids with extraordinary electrochemical performance for Li-ion batteries

2015; Nature Portfolio; Volume: 6; Issue: 1 Linguagem: Inglês

10.1038/ncomms7127

2041-1723

Qi Liu, Zhefei Li, Yadong Liu, Hangyu Zhang, Yang Ren, Cheng‐Jun Sun, Wenquan Lu, Yun Zhou, Lia Stanciu, Eric A. Stach, Jian Xie,

Supercapacitor Materials and Fabrication

The long-standing issues of low intrinsic electronic conductivity, slow lithium-ion diffusion and irreversible phase transitions on deep discharge prevent the high specific capacity/energy (443 mAh g−1 and 1,550 Wh kg−1) vanadium pentoxide from being used as the cathode material in practical battery applications. Here we develop a method to incorporate graphene sheets into vanadium pentoxide nanoribbons via the sol–gel process. The resulting graphene-modified nanostructured vanadium pentoxide hybrids contain only 2 wt. % graphene, yet exhibits extraordinary electrochemical performance: a specific capacity of 438 mAh g−1, approaching the theoretical value (443 mAh g−1), a long cyclability and significantly enhanced rate capability. Such performance is the result of the combined effects of the graphene on structural stability, electronic conduction, vanadium redox reaction and lithium-ion diffusion supported by various experimental studies. This method provides a new avenue to create nanostructured metal oxide/graphene materials for advanced battery applications. Vanadium pentoxide is considered a promising lithium battery electrode, but suffers from poor rate capability and cyclability. Here, the authors synthesize graphene-modified nanostructured vanadium pentoxide and show significant improvement in rate performance and cycle life.