Characterization of electrode fouling during electrochemical oxidation of phenolic pollutant

Electrode fouling is a problem that commonly occurs during electro-oxidation water purification. This study focused on identifying the fouling behavior of Pt electrode associated with the formation of polymeric layer during electro-oxidation of phenol. The in situ electrochemical measurements and non-destructive observation of the electrode morphology were reported. The results demonstrated that the electrode fouling was highly dependent on thermodynamic process of electrode that was controlled by anode potential. At anode potential lower than 1.0 V vs SHE, the direct electro-oxidation caused the electrode fouling by the formation of polymeric film. The fouling layer decreased the electrochemically active surface area from 8.38 cm(2) to 1.57 cm(2), indicated by the formation of polymeric film with thickness of 2.3 mu m, increase in mass growing at a rate of 3.26 mu g/cm/min. The degree to which the anode was fouled was independent of anion in the electrolyte. In comparison, at anode potential higher than 2.7 V vs SHE, the anions (e.g., chloride) could exert a major influence to the behavior of electrode fouling. The presence of chloride was shown to mitigate the fouling of electrode significantly through preventing the formation of polymeric film by active chlorine (e.g., Cl center dot and Cl-2) produced from anodic oxidation of chloride. Since chloride is the most abundant anionic species existing in both natural and engineered water system, this study not only offers a deep insight into the mechanism of electrode fouling, but also suggests strategies for anti-fouling in the presence of chloride in electro-oxidation process. (c) Higher Education Press 2020

Automated summary

The study reveals that electrode fouling during electro-oxidation water purification is highly dependent on the thermodynamic process controlled by anode potential. At lower anode potential, direct electro-oxidation leads to polymeric film formation, while at higher anode potential, the presence of chloride significantly influences electrode fouling behavior.