Hydroxyl radicals in anodic oxidation systems: generation, identification and quantification

Anodic oxidation has emerged as a promising treatment technology for the removal of a broad range of organic pollutants from wastewaters. Hydroxyl radicals are the primary species generated in anodic oxidation systems to oxidize organics. In this review, the methods of identifying hydroxyl radicals and the existing debates and misunderstandings regarding the validity of experimental results are discussed. Consideration is given to the methods of quantification of hydroxyl radicals in anodic oxidation systems with particular attention to approaches used to compare the electrochemical performance of different anodes. In addition, we describe recent progress in understanding the mechanisms of hydroxyl radical generation at the surface of most commonly used anodes and the utilization of hydroxyl radical in typical electrochemical reactors. This review shows that the key challenges facing anodic oxidation technology are related to i) the elimination of mistakes in identifying hydroxyl radicals, ii) the establishment of an effective hydroxyl radical quantification method, iii) the development of cost effective anode materials with high corrosion resistance and high electrochemical activity and iv) the optimization of electrochemical reactor design to maximise the utilization efficiency of hydroxyl radicals.

Automated summary

Anodic oxidation is a promising treatment technology for removing organic pollutants from wastewaters. Hydroxyl radicals are the primary species used for oxidizing organics. This review discusses the methods of identifying hydroxyl radicals, debates on the validity of experimental results, and quantification methods. It also highlights the generation mechanisms of hydroxyl radicals and their utilization in electrochemical reactors. The key challenges for anodic oxidation technology are identified as eliminating errors in identification, establishing effective quantification methods, developing cost-effective anode materials, and optimizing reactor designs for maximum utilization efficiency of hydroxyl radicals.