MOF‐Derived FeCoO/N‐Doped C Bifunctional Electrode for H<sub>2</sub> Production Through Water and Glucose Electrolysis
Meysam Tayebi, Zohreh Masoumi, Hyungwoo Lee, Daehyeon Hong, Bongkuk Seo, Choong‐Sun Lim, Daeseung Kyung, Hyeon‐Gook Kim
Abstract
Abstract The glucose oxidation reaction (GOR) is a potential alternative to water oxidation because of its relatively low thermodynamic potential and the high availability of glucose. Herein, a FeCoO/N‐doped C electrode derived from metal–organic framework (MOF) materials is applied, which is synthesized in several steps through the controlled deposition of Fe–Co oxide nanocatalysts onto Co –N‐doped C nanofibers on a Ni foam substrate and demonstrate exceptional electrocatalytic activity for both the GOR and overall water splitting. Here, a bifunctional electrocatalyst derived from MOF, FeCoO/N‐doped C is reported, for glucose oxidation reaction (GOR) and hydrogen evolution reaction (HER). The MOF‐derived FeCoO/N‐doped C (+/‐) as a bifunctional electrocatalyst exhibits a cell voltage of 1.4 V for the GOR&HER, to reach a current density of 10 mA cm −2 , which is 280 mV lower than that for the oxygen evolution reaction (OER)&HER (1.68 V). This study reveals that GOR is an energy‐efficient and affordable source of H 2 and value‐added chemicals.