2019
DOI: 10.1021/acs.est.8b07031
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Breakdown Products from Perfluorinated Alkyl Substances (PFAS) Degradation in a Plasma-Based Water Treatment Process

Abstract: Byproducts produced when treating perfluorooctanoic acid (PFOA) and perfluorooctanesulfonate (PFOS) in water using a plasma treatment process intentionally operated to treat these compounds slowly to allow for byproduct accumulation were quantified. Several linear chain perfluoroalkyl carboxylic acids (PFCAs) (C4 to C7) were identified as byproducts of both PFOA and PFOS treatment. PFOA, perfluorohexanesulfonate (PFHxS), and perfluorobutanesulfonate (PFBS) were also found to be byproducts from PFOS degradation… Show more

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Cited by 305 publications
(217 citation statements)
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“…Available forms of ARP (e.g., electron beam [eBeam], photolysis, ultra‐violet [UV]‐radiation, and plasma) use different mechanisms to disproportionate the water molecule (i.e., decomposes into both oxidizing and reducing species) into radicals (e.g., hydroxyl, hydrogen, hydroperoxyl, superoxide, and solvated electrons), which subsequently and sequentially defluorinate PFAS (Figure ). Plasma treatment uses a high voltage electrode to discharge successive electrical current pulses to a grounded electrode within a PFAS‐impacted aqueous solution (Singh et al ). The electrical current reacts with the water molecules, continuously generating oxidizing and reducing radicals.…”
Section: Considerations For Available Pfas‐relevant Destruction Technmentioning
confidence: 95%
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“…Available forms of ARP (e.g., electron beam [eBeam], photolysis, ultra‐violet [UV]‐radiation, and plasma) use different mechanisms to disproportionate the water molecule (i.e., decomposes into both oxidizing and reducing species) into radicals (e.g., hydroxyl, hydrogen, hydroperoxyl, superoxide, and solvated electrons), which subsequently and sequentially defluorinate PFAS (Figure ). Plasma treatment uses a high voltage electrode to discharge successive electrical current pulses to a grounded electrode within a PFAS‐impacted aqueous solution (Singh et al ). The electrical current reacts with the water molecules, continuously generating oxidizing and reducing radicals.…”
Section: Considerations For Available Pfas‐relevant Destruction Technmentioning
confidence: 95%
“…The alternative approaches are emerging as more mobile options using small‐scale plants, which could be applied at sites where PFAS waste concentrates are generated. Based on numerous sources, an approximate range of energy demand per volume treated for plasma, electrochemical treatment, and sonolysis is 0.01 to 0.5‐kW h per liter (kW‐h/L; 0.04 to 1.9 kW‐h per gallon [kW‐h/gal]; e.g., Gomez‐Ruiz et al ; Soriano et al ; Kempisty et al ; Nzeribe et al ; Singh et al , ). However, approximating a range of energy demand for these relevant technologies is difficult to accurately summarize due to the variety of operating conditions within the respective studies when the energy demand was determined.…”
Section: Identifying the Destructive Technology “Strike Zone”mentioning
confidence: 99%
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“…Several studies have tested the efficacy of these methods to determine if they reach temperatures high enough for a sufficient duration to allow for complete degradation [45,46]. Alternative methods to incineration such as mineralization of fluorinated compounds during thermal treatment, or a plasma based water treatment, are also being investigated as they may be safer and more efficient to treat waste [1,47,48].…”
Section: Thermal Degradation and Remediation For Solid Wastementioning
confidence: 99%
“…There are currently several methods being investigated to safely dispose of various PFAS waste, specifically end-of-life fluorinated polymers in materials [1,33,34,37,45,46,48,86]. These methods include open burning (OB), open air detonation (OD), incineration, pyrolysis, and smoldering.…”
Section: Definition Of Thermal Degradationmentioning
confidence: 99%