Abstract
Developing a highly efficient and stable catalyst, composited by inexpensive, earth-abundant and nontoxic materials, is the critical issue for electrochemical urea oxidation. Among the all other physical parameters, the reaction temperature plays the key role in catalyst performance. Herein, we have studied the effect of temperatures on the synthesis of nickel hydroxide-carbon nanotubes composites via a facile hydrothermal method and the catalytic performance towards urea electro-oxidation in detail. Our studies indicate that the higher temperature enhances the crystallinity of beta-Ni(OH)(2) species. Furthermore, the Ni(III) species in Ni(OH)(2)-CNTs composites show an optimal point upon the changes of the reaction temperature, and the highest Ni(III) content appears at 80 degrees C of beta-Ni(OH)(2)-CNTs. Meanwhile, electrochemical studies show that the electrochemically active surface areas (ESA) of the optimized beta-Ni(OH)(2)-CNTs (80 degrees C, 95.6 m(2) g(-1)) catalyst is 4.51- and 2.76-fold higher than that of beta-Ni(OH)(2)-CNTs synthesized at 20 and 140 degrees C, respectively. The higher ESA of beta-Ni(OH)(2)-CNTs (80 degrees C) also accompanies a superior electrochemical urea oxidation with a peak current density of 98.5 mA cm(-2), significantly higher than all the other studied catalysts. Additionally, the optimal beta-Ni(OH)(2)-CNTs (80 degrees C) also demonstrates the highest initial and limiting current densities after uninterrupted long-term operation. These excellent performance of beta-Ni(OH)(2)-CNTs (80 degrees C) catalyst indicates the positive effect of Ni(III) content which provides more catalytically active species along with the unique lamellar structures of CNTs as the support to facilitate electron/mass transfer and gas emission. (C) 2019 Elsevier Ltd. All rights reserved.