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New Mechanistic Insights into the Transformation of Reactive Oxidizing Species in an Ultraviolet/Sulfite System under Aerobic Conditions: Modeling and the Impact of Mn(II)

Dandan Rao, Hongyu Dong, Lushi Lian, Yuankui Sun, Xin Zhang, Lei Dong, Gongming Zhou, Xiaohong Guan

2021ACS ES&T Water61 citationsDOI

Abstract

Sulfite [S(IV)] photolyzed with 254 nm ultraviolet (UV) light was used as a surrogate for S(IV)-based advanced oxidation processes (AOPs) to elaborate the S(IV) chain transformation process, which plays a pivotal role in S(IV)-based AOPs but is poorly understood. The level of degradation of ibuprofen in the UV/S(IV) system increased with an increase in the initiation rate of S(IV) chain transformation, and SO4•– was the major oxidant. Trace Mn(II) in the UV/S(IV) process promoted ibuprofen degradation, S(IV) transformation, and peroxymonosulfate production at pH 6.0–8.0 but inhibited these processes at pH 9.0. A mathematic model (model 1) was constructed for the UV/S(IV) system, and it revealed that 40% of dosed S(IV) was transformed to SO4•– but ∼95% of the generated SO4•– was reduced by S(IV), resulting in the low oxidation capacity of the UV/S(IV) system. Upon incorporation of the reactions related to Mn(II)/Mn(III) transformation into model 1, model 2 was built to simulate the transformation kinetics of S(IV), ibuprofen, and peroxymonosulfate in the UV/Mn(II)/S(IV) system, which demonstrated that Mn(III) tended to oxidize S(IV) and worked as a chain carrier at pH 6.0–8.0 but was apt to disproportionate and acted as a chain terminator at pH 9.0. These results will guide the efforts to optimize the performance of S(IV)-based AOPs.

Topics & Concepts

ChemistrySulfiteOxidizing agentTransformation (genetics)KineticsUltravioletDegradation (telecommunications)Nuclear chemistryInorganic chemistryOrganic chemistryBiochemistryGeneQuantum mechanicsComputer sciencePhysicsTelecommunicationsAdvanced oxidation water treatmentPharmaceutical and Antibiotic Environmental ImpactsElectrochemical Analysis and Applications
New Mechanistic Insights into the Transformation of Reactive Oxidizing Species in an Ultraviolet/Sulfite System under Aerobic Conditions: Modeling and the Impact of Mn(II) | Litcius