2020
DOI: 10.1021/acs.est.0c02158
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Removal of Poly- and Per-Fluorinated Compounds from Ion Exchange Regenerant Still Bottom Samples in a Plasma Reactor

Abstract: “High-concentration” and “low-concentration” bench-scale batch plasma reactors were used to effectively degrade per- and polyfluoroalkyl substances (PFAS) at a high concentration (∼100 mg/L) and a low concentration (<1 μg/L), respectively, in ion exchange (IX) regenerant still bottom (SB) solutions. In the SBs, numerous PFAS were detected with a wide concentration range (∼0.01 to 100 mg/L; total oxidizable precursors (TOP) ∼4000 to 10000 mg/L). In the “high-concentration” plasma reactor, the concentrations of … Show more

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Cited by 73 publications
(47 citation statements)
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“…Since hydrodefluorination cannot be avoided during UV/sulfite treatment, an oxidative post-treatment is usually required to cleave the remaining C–F bonds in H-rich residues. These mechanistic insights will benefit the development and understanding of PFAS treatment technologies such as photochemical degradation in homogeneous and heterogeneous systems, electrochemical degradation, and plasma treatment, where reductive and/or oxidative processes are involved. The HO • oxidation results also provide data to compare with similar reaction systems , and achieve a deeper mechanistic understanding.…”
Section: Resultsmentioning
confidence: 99%
“…Since hydrodefluorination cannot be avoided during UV/sulfite treatment, an oxidative post-treatment is usually required to cleave the remaining C–F bonds in H-rich residues. These mechanistic insights will benefit the development and understanding of PFAS treatment technologies such as photochemical degradation in homogeneous and heterogeneous systems, electrochemical degradation, and plasma treatment, where reductive and/or oxidative processes are involved. The HO • oxidation results also provide data to compare with similar reaction systems , and achieve a deeper mechanistic understanding.…”
Section: Resultsmentioning
confidence: 99%
“…To degrade additional PFAAs, another plasma reactor was used for low concentrations. In this reactor, the authors added a cationic surfactant (cetrimonium bromide) which promoted the removal of short-chain PFAAs (below detection limits) in 1.5 h. Overall, .99% of PFAS from wastewater was removed during the treatment with corresponding fluorine recoveries of 47%-117% (Singh et al 2020b).…”
Section: Plasma-based Technologiesmentioning
confidence: 99%
“…The adverse health effects of long-chain PFAS have prompted a phase-out of C8-based chemicals and a shift toward short-chain alternatives. A large variety of PFAS with various fluoroalkyl chain lengths and functional groups has been detected in the water environment worldwide. Although carbon adsorption, ion exchange, and nanofiltration can rapidly remove PFAS from polluted water, the concentrated PFAS in spent sorbents or membrane rejects require cost-effective destruction. Various PFAS destruction technologies have been under rapid development, such as wet oxidation, , plasma, , electrochemical, photochemical, , and sonochemical , approaches. Most technologies utilize strong oxidative species (e.g., hydroxyl radical HO•, sulfate radical SO 4 – •, and semiconductor hole) and/or reductive species (e.g., hydrated electron e aq – ).…”
Section: Introductionmentioning
confidence: 99%
“…4−9 Although carbon adsorption, ion exchange, and nanofiltration can rapidly remove PFAS from polluted water, 10−13 the concentrated PFAS in spent sorbents or membrane rejects require cost-effective destruction. Various PFAS destruction technologies have been under rapid development, such as wet oxidation, 14,15 plasma, 16,17 electrochemical, 18−20 photochemical, 21,22 and sonochemical 23,24 approaches. Most technologies utilize strong oxidative species (e.g., hydroxyl radical HO•, sulfate radical SO 4 − •, and semiconductor hole) and/or reductive species (e.g., hydrated electron e aq − ).…”
Section: ■ Introductionmentioning
confidence: 99%