Sustainable energy generation through engineered copper molybdate: a ternary metal oxide catalyst for efficient oxygen evolution in alkaline environments

The world is currently facing an energy shortage, and renewable hydrogen technology is regarded as a key alternative to fossil fuels. Among these technologies, water splitting processes, such as oxygen evolution reaction (OER) and hydrogen evolution reaction (HER), have attracted significant attention for their environmentally friendly nature. This study focuses on the synthesis and application of copper molybdate (Cu₃Mo₂O₉) based ternary metal oxides (TMOs), which exhibits an orthorhombic crystal structure, variable oxidation states, and excellent redox properties, making it highly promising for applications in electrocatalysis and energy storage. Using the hydrothermal method, the reaction solution pH was adjusted to identify the sample with optimal crystallinity and structural characteristics. Experimental results show that Cu₃Mo₂O₉ nanoparticles with superior crystallinity was successfully synthesized at pH 11. The optimized pH electrocatalyst exhibits better OER with an overpotential of 170 mV at a current density of 10 mA cm⁻² and Tafel value of 153 mV/dec. TMOs have high specific capacitance and excellent stability, highlighting its potential as an energy material.