Structure and electrochemical performance of graphene/porous carbon coated carbon nanotube composite for supercapacitors

A composite of graphene/porous carbon coated carbon nanotube (denoted as RGO/CNT@AC) is synthesized. Microstructural characterization of the RGO/CNT@ AC composite shows that the CNTs are uniformly coated by activated porous carbons, and the porous carbon coated CNTs are inserted among graphene sheet...

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Bibliographic Details
Published in:Materials letters 2015-12, Vol.160, p.190-193
Main Authors: Zhang, Xuesha, Jin, Jianglong, Yan, Pengtao, Xu, Jiang, Zhang, Ruijun, Wu, Chao
Format: Article
Language:English
Subjects:
Capacitance
Capacitors
Carbon
Carbon nanotube
Carbon nanotubes
Coating
Composite materials
Electrolytes
Graphene
Porous materials
Supercapacitive performance
Supercapacitors
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Summary:A composite of graphene/porous carbon coated carbon nanotube (denoted as RGO/CNT@AC) is synthesized. Microstructural characterization of the RGO/CNT@ AC composite shows that the CNTs are uniformly coated by activated porous carbons, and the porous carbon coated CNTs are inserted among graphene sheets. Electrochemical investigations indicate that the specific capacitance of the RGO/CNT@AC composite is up to 147Fg−1 at 10mVs−1, an 56% improvement compared with that of graphene/pure CNT (denoted as RGO/CNT) composite. Furthermore, the cyclic voltammogram curves of the RGO/CNT@AC composite can keep a rectangular-like shape even at a scan rate of 5000mVs−1, showing a significantly better rate capability. The improvement in supercapacitive performance of the RGO/CNT@AC composite may be attributable to the contribution of porous carbon to specific capacitance, the effective inhibition the restacking of graphene sheets and the construction of more mutually connected electrolyte ions transport paths by the shortened porous carbon coated CNTs among graphene sheets. The superior specific capacitance and rate performance imply that the RGO/CNT@AC composite is promising for supercapacitors. •A facile route for preparing RGO/CNT@AC composite is developed.•Introducing CNT@AC instead of CNT among RGOs is beneficial to specific capacitance.•RGO/CNT@AC composite exhibits superior specific capacitance and rate performance.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2015.07.090