Abstract
Hydrated electrons (e-aq,E= -2.9 V) generated by advanced reduction processes (ARPs) have been proved to be a promising approach to eliminate various per- and polyfluoroalkyl substances (PFASs) in water. In this study, the decomposition of perfluorooctanoic acid (PFOA) in a complex water matrix by e-aq generated from the UV/sulfite process was investigated. The effect of pH (9–12) and co-existing compounds (chloride, nitrate, phosphate, carbonate and humic acid) on PFOA degradation efficiency was studied. In addition, the intermediates and possible degradation pathways were analyzed by ultra-high performance liquid chromatography-tandem mass spectrometry (UPLC-MS). The results showed that the concentration of PFOA was below the detection limit (10 μg/L) after 1 h (conditions: C0 10 mg/L, initial pH = 10, sulfite 10 mM) while 89% defluorination was achieved after 24 h. Using a higher initial pH (pH = 12) greatly enhanced the PFOA degradation as 100% degradation and 98% defluorination were achieved after 24 h. The presence of carbonate (> 5 mM), nitrate (> 2 mM) and humic acid (> 25 mg/L) showed a significant negative effect on PFOA degradation via a UV blocking effect or quenching of hydrated electrons while the presence of chloride and phosphate had a smaller effect on PFOA degradation. Even at extremely high concentrations of chloride (1.709 M, pH = 11.25), the defluorination ratio reached 97% after 24 h of reaction time. During the process, short-chain perfluorinated carboxylic acids (PFCAs, C < 7) and hydrogen substituted compounds were detected, which implies that chain-shortening and H/F change reactions had occurred. Moreover, this confirmed the generation of sulfonated and unsaturated intermediates during the process, which disclosed valuable new mechanistic insights into PFOA degradation.
Highlights
Per- and polyfluoroalkyl substances (PFASs) are a group of anthro pogenic compounds in which at least one or all hydrogen atoms attached to the carbon chain are replaced by fluorine
We identified new sulfonated and unsaturated intermediates that are being re ported for the first time, which revealed new information on the per fluorooctanoic acid (PFOA) degradation pathways and mechanisms in the UV/sulfite process
A strong reducing species, e-aq generated by the UV/sulfite process, was successfully applied to PFOA degradation in the current study
Summary
Per- and polyfluoroalkyl substances (PFASs) are a group of anthro pogenic compounds in which at least one or all hydrogen atoms attached to the carbon chain are replaced by fluorine. Because of their high thermal stability, low chemical activity and good water-resistant prop erties, PFASs have been widely used in many products, such as food packaging, firefighting foams, textiles and personal care products (Cui et al, 2020; Gagliano et al, 2020; Wu et al, 2020). The decomposition of PFOA has been found to be extremely slow in the natural environment due to the high strength of the carbon-fluorine bond (Li et al, 2020; Sunderland et al, 2019). It is important to develop a feasible method to eliminate PFOA contamination from water
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