Improvement of electrochemical characteristics by changing morphologies of carbon electrode
- Authors
- Min, H.S.; Kim, S.; Cheong, D.-S.; Choi, W.K.; Oh, Y.J.; Lee, J.-K.
- Issue Date
- 2009-10
- Citation
- Korean Journal of Materials Research, v.19, no.10, pp.544 - 549
- Abstract
- Activated carbon (AC) with very large surface area has high capacitance per weight. However, such activation methods tend to suffer from low yields, below 50%, and are low in electrode density and capacitance per volume. Carbon NanoFibers (CNFs) had high surface area polarizability, high electrical conductivity and chemical stability, as well as extremely high mechanical strength and modulus, which make them an important material for electrochemical capacitors. The electrochemical properties of immobilized CNF electrodes were studied for use as in electrical double layer capacitor (EDLC) applications. Immobilized CNFs on Ni foam grown by thermal chemical vapor deposition (CVD) were successfully fabricated. CNFs had a uniform diameter range from 50 to 60 nm. Surface area was 56 m2/g. CNF electrodes were compared with AC and multi wall carbon nanotube (MWNT) electrodes. The electrochemical performance of the various electrodes was examined with aqueous electrolyte of 2M KOH. Equivalent series resistance (ESR) of the CNF electrodes was lower than that of AC and MWNT electrodes. The specific capacitance of 47.5 F/g of the CNF electrodes was achieved with discharge current density of 1 mA/cm2.
- Keywords
- Activation method; Aqueous electrolyte; Carbon electrode; Discharge current density; Electric double layer capacitor; Electrical double layer capacitor; Electrochemical capacitor; Electrochemical characteristics; Electrochemical performance; Equivalent series resistance; High electrical conductivity; High mechanical strength; High surface area; KOH electrolyte; Large surface area; Low-yield; Multi-wall carbon nanotubes; Ni foam; Polarizabilities; Specific capacitance; Surface area; Thermal chemical vapor deposition; Uniform diameter; Activated carbon; Capacitance; Capacitors; Carbon nanofibers; Carbon nanotubes; Chemical stability; Chemical vapor deposition; Electric conductivity; Electric discharges; Electrochemical properties; Electrochemistry; Electrolysis; Electrolytes; Intelligent materials; Surfaces; Electrochemical electrodes; Activation method; Aqueous electrolyte; Carbon electrode; Discharge current density; Electric double layer capacitor; Electrical double layer capacitor; Electrochemical capacitor; Electrochemical characteristics; Electrochemical performance; Equivalent series resistance; High electrical conductivity; High mechanical strength; High surface area; KOH electrolyte; Large surface area; Low-yield; Multi-wall carbon nanotubes; Ni foam; Polarizabilities; Specific capacitance; Surface area; Thermal chemical vapor deposition; Uniform diameter; Activated carbon; Capacitance; Capacitors; Carbon nanofibers; Carbon nanotubes; Chemical stability; Chemical vapor deposition; Electric conductivity; Electric discharges; Electrochemical properties; Electrochemistry; Electrolysis; Electrolytes; Intelligent materials; Surfaces; Electrochemical electrodes; Carbon nanofiber; EDLC (electric double layer capacitor); Equivalent series resistance; KOH electrolyte; Raman
- ISSN
- 1225-0562
- URI
- https://pubs.kist.re.kr/handle/201004/132141
- DOI
- 10.3740/MRSK.2009.19.10.544
- Appears in Collections:
- KIST Article > 2009
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