Metal-doping induced catalytic suitability of CoWO4@3D-printed electrode for nitrate reduction coupled glycerol oxidation

Multimetallic site engineering is emerging as a powerful strategy to regulate electronic structure and reaction pathways in complex multielectron electrocatalytic systems, such as electrocatalytic nitrate reduction. Here, we report the rational design of transition metal-doped CoWO 4 (M-CoWO 4 , M = Cu, Fe, Ni) integrated into 3D-printed octet lattice electrodes for the electrochemical conversion of nitrate to ammonia (NO 3 ⁻-to-NH 3 ) coupled glycerol oxidation (GOR). Systematic experiments, in situ Raman analysis and density functional theory calculations reveal that metal doping modulates the electronic environment around active sites through charge redistribution, thereby tuning intermediate adsorption and catalytic performance. Cu doping enhances NOₓ⁻ adsorption and lowers the energy barrier for sequential protonation steps, accounting for the superior ammonia production rate (~2 mmol cm -2 h -1 ) and high Faradaic efficiency (95%). By contrast, Fe doping preferentially enhances oxidative catalysis, including OER and GOR. In a full-cell configuration, GOR-coupled nitrate reduction decreases power consumption by ~22% and boosts NH 3 yield rate by 2.5-fold relative to the conventional NITRR||OER system. This study reveals that strategic metal doping in CoWO 4 tunes its electronic structure to promote energy-efficient NO 3 ⁻-to-NH 3 conversion coupled with glycerol oxidation, offering a sustainable pathway toward green ammonia production. • Micro/nanoplastics threaten ecosystems due to synthetic polymeric product usage. • Magnetically actuated microrods actively target nanoplastics in water. • Microrobotic approach enables externally controllable water remediation processes.