Controlled Electrocatalytic Glycerol Upgrading to Glyceraldehyde in Near Neutral Media by Cobalt Oxide Lattice Activation

Electrocatalytic upgrading of biomass‐derived glycerol driven by renewable electricity offers a greatly attractive green way to produce value‐added chemicals at much reduced global carbon footprint. However, achieving both the enhanced activity and selectivity for the most‐valuable C3 product‐‐glyceraldehyde (GAD) of glycerol oxidation reaction (GOR) in neutral media, though of great importance, is extremely challenging. In this work, we propose a Co3O4 lattice activation mechanism by introducing single atom Ru (0.36 wt%) into the CoTd sites of Co3O4 lattice to significantly elevate the GOR activity and the GAD selectivity by GOR. The as‐constructed Ru‐Co3O4/NF only needs 1.16 V to achieve the current density of 10 mA cm‐2 during GOR and maintains ~60% GAD selectivity (~90% for C3 products) over a broad potential window, which are the highest reported in near neutral media. This excellent performance has been demonstrated to originate from the introduction of Ru atoms, which activates the lattice active sites of Co3O4 by promoting the rapid reconstruction of the catalyst to generate sufficient Co3+‐(OH)ads electrophilic oxygen species, resulting in not only the accelerated GOR kinetics, also largely enhanced selectivity of GAD by the adsorption configuration regulation of glycerol primary alcohols (Cα‐OH) favoring the primary alcohol oxidation pathway.