Abstract
Electrochemical water splitting is considered a promising way of producing hydrogen and oxygen for various electrochemical energy devices. An efficient single, bi-functional electrocatalyst that can perform hydrogen evolution reactions (HERs) and oxygen evolution reactions (OERs) is highly essential. In this work, Co@NC core-shell nanoparticles were synthesized via a simple, eco-friendly, solid-state synthesis process, using cobalt nitrate and with pyrazole as the N and C source. The morphological analysis of the resulting Co@NC nanoparticles was performed with a scanning and transmission electron microscope, which showed Co nanoparticles as the core and the pyrolysis of pyrazole organic ligand N-doped carbon derived shell structure. The unique Co@NC nanostructures had excellent redox sites for electrocatalysis, wherein the N-doped carbon shell exhibited superior electronic conductivity in the Co@NC catalyst. The resulting Co@NC nanocatalyst showed considerable HER and OER activity in an alkaline medium. The Co@NC catalyst exhibited HERs overpotentials of 243 and 170 mV at 10 mA∙cm−2 on glassy carbon and Ni foam electrodes, respectively, whereas OERs were exhibited overpotentials of 450 and 452 mV at a current density of 10 and 50 mA∙cm−2 on glassy carbon electrode and Ni foam, respectively. Moreover, the Co@NC catalyst also showed admirable durability for OERs in an alkaline medium.
Highlights
The increased global energy demand due to the increasing population escalates the use of greenhouse gas emitting fossil fuels, which has researchers searching for alternative, efficient, sustainable, and less carbon emission-free technologies
A calculated amount of the precursors were taken (Co2+, pyrazole, and Zn2+ ) together into a mortar and mechanically ground with a pestle for about 30 min, which leads to the formation of a sticky pink-colored paste, which upon drying produced a solid pink colored powder
As in our proposed mechanism for forming self-assembled metal-organic frameworks (MOFs) structures in our previous work [15], during the ground with a pestle for about 30 min, which leads to the formation of a sticky pink-colored paste, which upon drying produced a solid pink colored powder
Summary
The increased global energy demand due to the increasing population escalates the use of greenhouse gas emitting fossil fuels, which has researchers searching for alternative, efficient, sustainable, and less carbon emission-free technologies In this regard, electrochemical water splitting is considered a promising technology for obtaining hydrogen for energy-producing technology like hydrogen-based fuel cells and regenerative fuel cells [1]. The hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), during the electrolysis process, occurs at a cathode and anode, respectively. Both reactions require highly active electrocatalysts such as Pt-based catalysts for cathodes and Ir/Ru-based catalysts for anodes. Acidic-based water electrolysis systems are widespread, they are limited, hindering
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