| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Research Progress of Carbon-based Composite Electrode MaterialsUsed for Stretchable Supercapacitors |
| YUE Ruirui, WANG Huicai, LIU Xiaping, YANG Jibin, WANG Zhenwen
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| School of Environmental and Chemistry Engineering, Tianjin Polytechnic University, Tianjin 300387 |
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Abstract The emergence of portable and wearable electronic products is now spurring the demands for flexible energy storage devices. The prevailing energy storage devices are Li-ion batteries and supercapacitors, in which the latter have the advantages of faster charging/discharging, higher cycle stability and larger specific capacitance. However, traditional supercapacitors will suffer a storage capacity fall if they are subjected to external forces such as stretching and compressing. Thus stretchable supercapacitors have already aroused great concern.
Electrode is a critical part of stretchable supercapacitors. The electrochemical and mechanical properties of electrodes can be improved by preparing electrode materials with excellent properties or designing electrode structures adapted or resistant to severe mechanical forces, e.g. compression, tension and torsion. Carbon materials such as carbon nanotubes, graphene, carbon fibers and carbon aerogels belong to electric double-layer electrode materials. Although these materials have high cyclic stability and large surface area, they still have disadvantages such as low specific capacitance and low energy density. Moreover, graphene faces the problem of deficient energy storage performance induced by stacking and agglomeration. The fabrication of carbon-based composite electrode materials, by combining carbon materials with other types of electrode materials, thereby has become a hot topic recently. Pseudocapacitor electrode materials with high specific capacitance, transition metal sulphides with high specific surface area, and metal nanowires with high electrical conductivity, all of them have been found to have collaborative & complementary effects with some of the carbon materials. And the resultant stretchable composite electrodes, compared with electrodes made of only carbon materials, seem to have obvious improvements in specific capacitance, cyclic stability and mechanical properties.
This paper gives a comparative presentation of the advantages and disadvantages of various carbon materials in use of stretchable supercapacitors. Then, the advances in carbon-based composite electrode materials that have acquired intensive research interest in recent years are reviewed.
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Published: 12 September 2019
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About author:: Ruirui Yue received her B.S. degree in applied che-mistry from Inner Anhui Normal University for the Nationalities in 2017. She is now a post-graduate student in the school of Environmental and Chemistry Engineering, Tianjin Polytechnic University. Her main research field is electrochemical sensor.
Huicai Wang received his B.E. degree in analytical chemistry from Changchun Institute of Technology in 2000 and received his Ph. D. degree in polymer chemistry and physics from Zhejiang University in 2007. After two years postdoctoral research at Nankai University, he is currently a full associate professor in Tianjin Polytechnic University. His research interest are functional materials and their applications in electrochemical detection, new energy materials and environmental mate-rials. |
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2019, Vol. 33 
