Emerging electrocatalytic conversion of NOx species into value-added nitrogenous chemicals
Review Article
Catalyst design strategies for NOx-involved electrocatalytic C–N coupling reactions
Five catalyst design strategies are proposed to enhance NOx-involved electrocatalytic C–N coupling: defect engineering, coordination environment regulation, interface modulation, dual-site synergy, and dynamic architectures.
Enhancing electrocatalytic activities of high-entropy borides (HEBs) for C–N coupling in induced cation and pH-dependent microenvironments via multiscale modeling strategy
High-entropy borides (HEBs) for C–N coupling in induced cation and pH-dependent microenvironments.
Boosting electrochemical urea synthesis via nitrous oxide and carbon oxide coupling over homonuclear dual-atom catalysts: a computational study
Boosting electrochemical urea synthesis via nitrous oxide and carbon oxide coupling over homonuclear dual-atom catalysts.
Efficient electrochemical coupling of nitrate and biomass-derived acetone to acetoxime at a high current density over a Zn/Cu hexagonal nanosheet catalyst
Efficient electrosynthesis of acetoxime from nitrate and acetone at a high current density over a novel Zn/Cu hexagonal nanosheet electrocatalyst.
About this collection
Welcome to Inorganic Chemistry Frontiers themed collection on Electrocatalytic C-N Coupling.
With the development of renewable energy, green electrosynthesis has ushered in new opportunities. Electrosynthesis of C-N coupled organonitrogen using carbonyl compounds and inorganic nitrogen substances not only provides a sustainable and efficient method to produce valuable chemicals but also contributes to the exploration of life’s origins and the reduction of environmental pollution.
Guest edited by Graham J. Hutchings (Cardiff University), Shuangyin Wang (Hunan University), Guangqin Li (Sun Yat-sen University) and Ouardia Akdim (Cardiff University), this themed collection focuses on gathering innovative insights and technologies to advance electrocatalytic C-N coupling, with the goal of developing a carbon-neutral strategy for environmentally benign synthesis of high-value organonitrogen compounds.
More articles will be added as soon as they are published.