Influence and mechanism of water matrices on H2O2-based Fenton-like oxidation processes: A review

Water matrices often coexist with the target pollutant during H2O2-based Fenton-like processes, which affects H2O2 activation and pollutant removal. Specifically, water matrices include inorganic anions (such as chloride, sulfate, nitrate, bicarbonate, carbonate and phosphate ions) and natural organic matters (such as humic acid (HA) and fulvic acid (FA)). In this review, the roles and mechanisms of water matrices in various Fenton-like systems were analyzed and summarized comprehensively. Carbonate and phosphate ions usually act as inhibitors. In contrast, the effects of other water matrices are usually controversial. Generally, water matrices can inhibit pollutants degradation through scavenging center dot OH, forming low reactive radicals, adsorbing on catalyst sites, and changing solution pH. However, inorganic anions can exhibit a promotion effect, which is attributed to their complexation with copper ions in mixed contaminants as well as with cobalt and copper ions in catalysts. Furthermore, the photo-reactivity of nitrate and the generation of secondary radicals with long lifetime are conducive to the promotion of inorganic anions. Besides, HA (FA) can be activated by external energy or act as electron shuttle, thus displaying a facilitative effect. This review will provide guidance for the practical applications of the Fenton-like process.

Automated summary

Water matrices, including inorganic anions and natural organic matters, have significant effects on H2O2-based Fenton-like processes. While carbonate and phosphate ions usually inhibit the process, the effects of other water matrices are controversial. Water matrices can inhibit pollutant degradation through various mechanisms, such as scavenging radicals and changing solution pH. However, inorganic anions can exhibit a promotion effect due to their complexation with metal ions. This review provides comprehensive analysis and guidance for the practical applications of the Fenton-like process.