2015
DOI: 10.1016/j.electacta.2014.11.116
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Functionalized Carbon Nanomaterial Supported Palladium Nano-Catalysts for Electrocatalytic Glucose Oxidation Reaction

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Cited by 77 publications
(35 citation statements)
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“…8 and Table 1, the j 0 s for Pt/CF 158nm and Pt/CF 309nm were 8.41 Â 10 À3 mA cm À2 and 7.39 Â 10 À3 mA cm À2 under a Tafel slope of 35 mV/decade and 32 mV/decade, respectively. The measured j 0 s for the prepared Pt/CF were higher than 6.2 Â 10 À4 mA cm À2 by carbon-nanotube-supported Pd nanocatalysts [43]. In addition, a comparison of j 0 shows the ranking Pt/CF 39nm > Pt/CF 158nm > Pt/CF 309nm , which suggests that the diameter and curvature of the CF can influence j 0 for D-glucose oxidation and the maximum catalytic power for D-glucose oxidation by Pt/CF 39nm , having the highest ERSA.…”
Section: Diameter Effect Of Cf Support For the Pt Nanoparticles For Cmentioning
confidence: 98%
“…8 and Table 1, the j 0 s for Pt/CF 158nm and Pt/CF 309nm were 8.41 Â 10 À3 mA cm À2 and 7.39 Â 10 À3 mA cm À2 under a Tafel slope of 35 mV/decade and 32 mV/decade, respectively. The measured j 0 s for the prepared Pt/CF were higher than 6.2 Â 10 À4 mA cm À2 by carbon-nanotube-supported Pd nanocatalysts [43]. In addition, a comparison of j 0 shows the ranking Pt/CF 39nm > Pt/CF 158nm > Pt/CF 309nm , which suggests that the diameter and curvature of the CF can influence j 0 for D-glucose oxidation and the maximum catalytic power for D-glucose oxidation by Pt/CF 39nm , having the highest ERSA.…”
Section: Diameter Effect Of Cf Support For the Pt Nanoparticles For Cmentioning
confidence: 98%
“…The j 0 s for Pd NC/DGF SECM and Pd NC/DGF CM were higher than those for DGF-free Pd NCs and Pd/C and 6.2 × 10 −4 mA · cm −2 for Pd nanocatalysts supported on a carboxylated carbon nanotube. 28 Typically, the electron transfer number (n) involved in an electrocatalytic reaction can be calculated from the Tafel slope (B). 56 …”
Section: Characterizations Ofmentioning
confidence: 99%
“…However, the catalyst dispersity on the surface of MWCNT has been considered as a critical factor for the electrocatalytic activity (Chen et al, 2015). In general, it is often not easy to obtain uniform distribution of catalyst particles on a pristine, unmodified MWCNT surface due to inert chemical reactivity.…”
Section: Introductionmentioning
confidence: 99%