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http://dx.doi.org/10.5916/jkosme.2016.40.10.894

Fabrication of nickel nanoparticles-embedded carbon particles by solution plasma in waste vegetable oil  

Pansuwan, Gun (Kamnoetvidya Science Academy)
Phuksawattanachai, Surayouth (Kamnoetvidya Science Academy)
Kerdthip, Kraiphum (Kamnoetvidya Science Academy)
Sungworawongpana, Nathas (Kamnoetvidya Science Academy)
Nounjeen, Sarun (Kamnoetvidya Science Academy)
Anantachaisilp, Suranan (Kamnoetvidya Science Academy)
Kang, Jun (Division of Marine Engineering, Korea Marinetime and Ocean Engineering)
Panomsuwan, Gasidit (NU-PPC Plasma Chemical Technology Laboratory, Chulalongkorn University)
Ueno, Tomonaga (Department of Materials, Physics and Energy Engineering, Nagoya university)
Saito, Nagahiro (Department of Materials, Physics and Energy Engineering, Nagoya university)
Pootawang, Panuphong (Department of Chemistry, Kamnoetvidya Science Academy)
Publication Information
Journal of Advanced Marine Engineering and Technology / v.40, no.10, 2016 , pp. 894-898 More about this Journal
Abstract
Solution plasma is a unique method which provides a direct discharge in solutions. It is one of the promising techniques for various applications including the synthesis of metallic/non-metallic nanomaterials, decomposition of organic compounds, and the removal of microorganism. In the context of nanomaterial syntheses, solution plasma has been utilized to produce carbon nanoparticles and metallic-carbon nanoparticle systems. The main purpose of this study was to synthesize nickel nanoparticles embedded in a matrix of carbon particles by solution plasma in one-step using waste vegetable oil as the carbon source. The experimental setup was done by simply connecting a bipolar pulsed power generator to nickel electrodes, which were submerged in the waste vegetable oil. Black powders of the nickel nanoparticles-embedded carbon (NiNPs/Carbon) particles were successfully obtained after discharging for 90 min. The morphology of the synthesized NiNPs/Carbon was investigated by a scanning electron microscope, which revealed a good dispersion of NiNPs in the carbon-particle matrix. The X-ray diffraction of NiNPs/Carbon clearly showed the co-existence of crystalline Ni nanostructures and amorphous carbon. The crystallite size of NiNPs (through the Ni (111) diffraction plane), as calculated by the Scherrer equation was found to be 64 nm. In addition, the catalytic activity of NiNPs/Carbon was evaluated by cyclic voltammetry in an acid solution. It was found that NiNPs/Carbon did not show a significant catalytic activity in the acid solution. Although this work might not be helpful in enhancing the activity of the fuel cell catalysts, it is expected to find application in other processes such as the CO conversion (by oxidation) and cyclization of organic compounds.
Keywords
Ni/Carbon nanoparticle; Solution plasma; Catalyst; Waste vegetable oil;
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