Double role of CTAB as a surfactant and carbon source in Ni-Mo2C/GA composite: As a highly active electrocatalyst for hydrogen evolution reaction

Abstract

Hydrogen (H2) is considered one of the energy sources and carriers of the future but its production on a big scale will be difficult for the foreseeable future. The electrocatalytic activity of materials strongly affects the water-splitting reaction. This present work describes the synthesis of a novel Ni-Mo2C/GA composite by hydrothermal and followed by a carbonization process. The dual role of CTAB in the synthesis of Mo2C acts as a surfactant and carbon source, resulting in improved morphology and hydrogen evolution reaction (HER) performance. The morphological images highlight the role of CTAB used for the synthesis of pure Mo2C and the characterization techniques demonstrate the carbon role of CTAB (carbon supplier) in Mo2C. The as-synthesized Mo2C was further incorporated with Ni and graphene aerogel (GA) to get a Ni-Mo2C/GA composite. The synthesized pure Mo2C, Ni-Mo2C, and Ni-Mo2C/GA composite were examined for the HER using a 0.5 M H2SO4 electrolyte. The Ni-Mo2C/GA composite demonstrated improved current density and low overpotential (61 mV@10 mA/cm2), low Tafel slope (52 mV/dec), enhanced active surface area, and stunning stability up to 2000 cycles without deactivation. Our findings reveal the cost-effective synthesis of Ni-Mo2C/GA composite as an effective cathode material for HER applications.