A Two‐Dimensional Cu‐Based Nanosheet Producing Formic Acid Via Glycerol Electro‐Oxidation in Alkaline Water

Abstract

AbstractThe sluggishness of the complementary oxygen evolution reaction (OER) is reckoned as one of the major drawbacks in developing an energy‐efficient green hydrogen‐producing electrolyzer. An array of organic molecule oxidation reactions, operational at a relatively low potential, have been explored as a substitute for the OER. Glycerol oxidation reaction (GOR) has emerged as a leading alternative in this context because glycerol, a waste of biodiesel manufacturing, has become ubiquitous and accessible due to the significant growth in the biodiesel sector in recent decades. Additionally, the GOR generates several value‐added organic compounds following oxidation that enhance the cost viability of the overall electrolysis reaction. In this study, a low‐cost, room temperature operable, and energy‐efficient synthetic methodology has been developed to generate unique two‐dimensional CuO nanosheets (CuO NS). This CuO NS material was embedded on a carbon paper electrode, which showcased excellent glycerol electro‐oxidation performance operational at a moderately low applied potential. Formic acid is the major product of this CuO NS‐driven GOR (Faradaic efficiency ~80 %), as it is formed primarily via the glyceraldehyde oxidation pathway. This CuO NS material was also active for oxidizing other abundant alcohols like ethylene glycol and diethylene glycol, albeit at a relatively poor efficiency. Therefore, this robust CuO NS material has displayed the potential to be used in large‐scale electrolyzers functioning with HER/GOR reactions.