Identification of the molecular pathways of RuO2 electroreduction by in-situ electrochemical surface-enhanced Raman spectroscopy

Abstract RuO2 is one of the most promising catalysts for oxygen evolution reaction (OER), a key reaction in water electrolysis. However, the fundamental insights about the structural evolution of RuO2 under different electrochemical environments remain unclear. Herein, the molecular reaction pathways of the electroreduction of RuOx in alkaline and neutral conditions are identified using in-situ electrochemical surface-enhanced Raman spectroscopy. Au@RuO2 core–shell nanostructures are fabricated to amplify the Raman signals of species adsorbed on RuOx surfaces. Using such core–shell nanostructures, direct spectroscopic evidences of OH intermediate during the RuO2 electroreduction process are obtained, which is further confirmed by D2O isotopic substitution experiments. A molecular pathway that RuO2 is reduced to Ru through a two-step reduction process has been proposed. This work provides insightful information on the structural evolution of RuOx with electrochemical environments.