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An advanced, efficient and highly durable of reduced graphene oxide/ platinum nanoparticles nanocomposite electrocatalyst fabricated via one-step method of the hydrothermal-assisted formic acid process for the electrocatalytic oxidation reaction of methanol

Hanifah, M. F. R. and Jaafar, J. and Othman, M. H. D. and Ismail, A. F. and Rahman, M. A. and Yusof, N. and Aziz, F. (2020) An advanced, efficient and highly durable of reduced graphene oxide/ platinum nanoparticles nanocomposite electrocatalyst fabricated via one-step method of the hydrothermal-assisted formic acid process for the electrocatalytic oxidation reaction of methanol. Solid State Sciences, 101 .

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Official URL: https://dx.doi.org/10.1016/j.solidstatesciences.20...

Abstract

The high-quality of reduced graphene oxide (rGO) supported platinum nanoparticles (PtNPs) was synthesized by a simple, efficient, rapid, clean, surfactant-free, and single-step of hydrothermal-assisted formic acid process. The as-synthesized rGO/PtNPs catalyst was extensively characterized in which demonstrated that the PtNPs have successfully anchored on the surface of rGO with the small average particle size of 4 nm. The evaluation of electrocatalytic activity and durability performance of the as-synthesized rGO/PtNPs nanocomposite catalyst towards methanol oxidation reaction (MOR) as well as the determination of electrochemical surface area (ECSA) were carried out by cyclic voltammogram and chronoamperometry. Besides, the as-prepared rGO/PtNPs nanocomposite catalyst has further proved the remarkably higher electrocatalytic property which exhibited superior maximum forward peak current density (64.04 mA/cm(2)) toward MOR in acidic media compared with Vulcan XC72/PtNPs (47.54 mA/cm(2)) and rGO/PdNPs (6.21 mA/cm(2)) catalysts owing to homogenous distribution and synergic effects of PtNPs with rGO as well as improved electron transfer by rGO. Moreover, the rGO/PtNPs nanocomposite catalyst still achieve the high current density even after 2900 s of continuous catalyst at 0.6 V. This study provides new insights into the production of superior electrocatalytic activity and durability of anode catalyst through a facile, low cost and clean synthesis approach for the enhancement of direct methanol fuel cell performance.

Item Type:Article
Uncontrolled Keywords:methanol oxidation reaction, pt catalyst, electrochemical surface area
Subjects:T Technology > TP Chemical technology
Divisions:Chemical and Energy Engineering
ID Code:86489
Deposited By: Narimah Nawil
Deposited On:30 Sep 2020 08:57
Last Modified:30 Sep 2020 08:57

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