Water splitting in water electrolyzers is an excellent green method to produce Hydrogen as an energy source. The anodic oxygen evolution reaction in water electrolyzers is a complex reaction with high overpotential and slow kinetics and requires metal oxide nanoparticles (nps) such as IrO₂ as catalysts. However, due to low abundance and high cost, their extensive use is limited. In this regard, in the present work, we have evaluated the electrochemical activity of IrO₂ nps supported on N-doped graphene with varying nitrogen amount.

The catalyst IrO₂-N-rGO is synthesized via pyrolysis in Ar atmosphere and followed by loading of IrO₂ on N-rGO via hydrothermal method using H₂IrCl₆ as the precursor. The extent of N-doping (1-8 wt%) was varied by changing the GO: urea weight ratio. XPS analysis of the synthesized IrO₂-N-rGO catalyst revealed that N is present in its pyridinic and quaternary forms. TEM micrograph of IrO₂-N-rGO catalyst showed well dispersed IrO₂ nps all over the wrinkled N-rGO sheets without agglomeration with an average particle diameter of 1.5 nm. Electrochemical activity measured via CV and LSV methods showed that the onset potential (1.45 V vs RHE) was nearly 50 mV less than that of IrO₂-rGO and higher current density was obtained for the synthesized catalyst as compared to the commercial IrO₂ powder. IrO₂-N-rGO with low Ir metal content and improved activity represents a potential low cost, robust candidate for OER catalytic applications.