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JOURNAL ARTICLE

Lithographically defined porous Ni–carbon nanocomposite supercapacitors

Xiaoyin XiaoThomas E. BeechemDavid R. WheelerDavid Bruce BurckelRonen Polsky

Year: 2013 Journal:   Nanoscale Vol: 6 (5)Pages: 2629-2633   Publisher: Royal Society of Chemistry
DOI: 10.1039/c3nr05751h
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Abstract

Ni was deposited onto lithographically-defined conductive three dimensional carbon networks to form asymmetric pseudo-capacitive electrodes. A real capacity of above 500 mF cm(-2), or specific capacitance of ∼2100 F g(-1) near the theoretical value, has been achieved. After a rapid thermal annealing process, amorphous carbon was partially converted into multilayer graphene depending on the annealing temperature and time duration. These annealed Ni-graphene composite structures exhibit enhanced charge transport kinetics relative to un-annealed Ni-carbon scaffolds indicated by a reduction in peak separation from 0.84 V to 0.29 V at a scan rate of 1000 mV s(-1).

Keywords:
Materials science Supercapacitor Annealing (glass) Nanocomposite Capacitance Graphene Horizontal scan rate Amorphous carbon Chemical engineering Carbon fibers Electrode Composite number Porosity Nanotechnology Capacitive sensing Amorphous solid Composite material Electrochemistry Chemistry Cyclic voltammetry Crystallography

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0.56
FWCI (Field Weighted Citation Impact)
27
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0.63
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Citation History

Topics

Supercapacitor Materials and Fabrication
Physical Sciences →  Materials Science →  Electronic, Optical and Magnetic Materials
Electrocatalysts for Energy Conversion
Physical Sciences →  Energy →  Renewable Energy, Sustainability and the Environment
Graphene research and applications
Physical Sciences →  Materials Science →  Materials Chemistry

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