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Reductive Dissolution Mechanisms of Manganese Oxide Mediated by Algal Extracellular Organic Matter and the Effects on 17α-Ethinylestradiol Removal

Zhicheng Liao, Huan He, Feiyuan Liu, Jingye Cui, Ziwei Guo, Danni Cui, Bin Huang, Hongwen Sun, Xuejun Pan

2024Environmental Science & Technology11 citationsDOI

Abstract

Reductive dissolution of manganese oxide (MnO x ) is a major process that improves the availability of manganese in natural aquatic environments. The extracellular organic matter (EOM) secreted by algae omnipresent in eutrophic waters may affect MnO x dissolution thus the fate of organic micropollutants. This study investigates the mechanisms of MnO x reductive dissolution mediated by EOM and examines the effects of this process on 17α-ethinylestradiol degradation. The influences of EOM concentration (1.0–20.0 mgC/L) and pH (6.0–9.0) in both dark and irradiated conditions were assessed. In the dark, EOM was found to facilitate MnO x reductive dissolution via the ligand-to-metal charge transfer (LMCT). The dissolution was further enhanced under irradiation, with the participation of superoxide ions (O 2 •– ). Higher EOM concentrations increased the contents of available reducing substances and O 2 •–, accelerating the reductive dissolution. Higher pH slowed the photoreductive dissolution rates, while O 2 •– -mediated reduction became more important. Polyphenols and highly unsaturated carbon and phenolic formulas in EOM were found to drive the reductive dissolution. Soluble reactive Mn(III) formed through reductive dissolution of MnO x effectively removed 17α-ethinylestradiol in solution. Overall, the findings regarding the mechanisms behind reductive dissolution of MnO x have broad implications for Mn geochemical cycles and organic micropollutant fate.

Topics & Concepts

ManganeseDissolutionManganese oxideChemistryOrganic matterInorganic chemistryOxideEnvironmental chemistryNuclear chemistryOrganic chemistryGeochemistry and Elemental AnalysisMicrobial Fuel Cells and BioremediationChromium effects and bioremediation