Plasma enhanced synthesis of N doped vertically aligned carbon nanofibers on 3D graphene |
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| Authors: | Siddharth Mishra Hung Nguyen Paa Kwasi Adusei Yu-Yun Hsieh Vesselin Shanov |
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| Affiliation: | 1. Department of Materials Science and Engineering, University of Cincinnati, OH, 45221 USA;2. Department of Chemical and Environmental Engineering, University of Cincinnati, OH, 45221 USA |
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| Abstract: | Graphene and carbon nanotubes/fibers (CNT/CNF) hybrid structures are emerging as frontier materials for high-efficiency electronics, energy storage, thermoelectric, and sensing applications owing to the utilization of extraordinary electrical and physical properties of both nanocarbon materials. Recent advances show a successful improvement in the structure and surface area of layered graphene by incorporating another dimension and structural form—three-dimensional graphene (3DG). In this study, vertically aligned CNFs were grown using plasma enhanced chemical vapor deposition on a relatively new form of compressed 3DG. The latter was synthesized using a conventional thermal chemical vapor deposition. The resulting free-standing hybrid material is in-situ N doped during synthesis by ammonia plasma and is produced in the form of a hybrid paper. Characterization of this material was done using electrochemical and spectroscopic measurements. The N doped hybrid showed relatively higher surface area and improved areal current density in electrochemical measurements than compressed pristine 3DG, which makes it a potential candidate for use as an electrode material for supercapacitors, sensors, and electrochemical batteries. |
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| Keywords: | CNF CNT CVD graphene N doping plasma |
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