ChemElectroChem
ChemElectroChem
4 years ago

Embedding Reduced Graphene Oxide in Bacterial Cellulose-Derived Carbon Nanofibril Networks for Supercapacitors

Embedding Reduced Graphene Oxide in Bacterial Cellulose-Derived Carbon Nanofibril Networks for Supercapacitors
Lu Zhou, Yanhong Chang, Xinghao Zhang, Debin Kong, Zhichang Xiao, Linjie Zhi, Jiaxu Liang, Xianglong Li, Zihao Li
A simple, effective, eco-friendly, and scalable reduced graphene oxide embedding strategy is developed to construct self-supported carbon electrode material networks for supercapacitors from a naturally occurring biomaterial−bacterial cellulose. The thus-engineered self-supported carbon nanofibril networks exhibit superior supercapacitive performance compared to their counterparts, thus opening up an avenue to design self-supported high-capacitance carbon electrode materials toward high-class supercapacitors. Get networking: A simple, effective, eco-friendly, and scalable reduced graphene oxide embedding strategy is developed to construct self-supported, high-capacitance carbon electrode material networks for high-class supercapacitors from a naturally occurring biomaterial−bacterial cellulose.

Publisher URL: http://onlinelibrary.wiley.com/resolve/doi

DOI: 10.1002/celc.201700625

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