Electrochemical Transformations of Perfluoroalkyl Acid (PFAA

Aug 22, 2018 - Nicholas School of the Environment, Duke University, Durham, North ... and Environmental Engineering, Colorado School of Mines, Golden,...
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Electrochemical Transformations of Perfluoroalkyl Acid (PFAA) Precursors and PFAAs in Groundwater Impacted with Aqueous Film Forming Foams Charles E. Schaefer, Sarah Choyke, P. Lee Ferguson, Christina Andaya, Aniela Burant, Andrew Chapin Maizel, Timothy J. Strathmann, and Christopher P. Higgins Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b02726 • Publication Date (Web): 22 Aug 2018 Downloaded from http://pubs.acs.org on August 22, 2018

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Electrochemical Transformations of Perfluoroalkyl Acid (PFAA) Precursors and PFAAs in Groundwater Impacted with Aqueous Film Forming Foams

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Charles E. Schaefer1,*, Sarah Choyke2, P. Lee Ferguson2, Christina Andaya3, Aniela Burant4, Andrew Maizel4, Timothy J. Strathmann4, Christopher P. Higgins4 CDM Smith, 110 Fieldcrest Avenue, #8, 6th Floor, Edison, NJ 08837

1

2

Nicholas School of the Environment, Duke University, Durham, North Carolina 27708, United States 3

APTIM, 17 Princess Road, Lawrenceville, NJ 08648

4

Department of Civil and Environmental Engineering, Colorado School of Mines, Golden, CO 80401

*

CORRESPONDING AUTHOR: Mailing address: CDM Smith, 110 Fieldcrest Avenue, #8, 6th Floor, Edison, NJ 088837. (732)-590-4633. E-mail: [email protected]

Submitted to Environmental Science & Technology

Key Words: PFOS, PFOA, electrochemical, boron-doped diamond, AFFF

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Abstract

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While oxidative technologies have been proposed for treatment of waters impacted by

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aqueous film forming foams (AFFFs), information is lacking regarding the

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transformation pathways for the chemical precursors to the perfluoroalkyl acids (PFAAs)

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typically present in such waters. This study examined the oxidative electrochemical

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treatment of poly- and perfluoroalkyl substances (PFASs) for two AFFF-impacted

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groundwaters. The bulk pseudo first order rate constant for PFOA removal was 0.23 L h-1

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A-1; for PFOS, this value ranged from 0.084 to 0.23 L h-1 A-1. Results from the first

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groundwater studied suggested a transformation pathway where sulfonamide-based

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PFASs transformed to primarily perfluorinated sulfonamides and perfluorinated

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carboxylic acids (PFCAs), with subsequent defluorination of the PFCAs. Transient

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increases in the perfluorinated sulfonamides and PFCAs were observed. For the second

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groundwater studied, no transient increases in PFAAs were measured, despite the

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presence of similarly structured suspected PFAA precursors and substantial

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defluorination. For both waters, suspected precursors were the primary sources of the

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generated fluoride. Assessment of precursor compound transformation noted the

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formation of keto-perfluoroalkane sulfonates only in the second groundwater. These

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results confirm that oxidation and defluorination of suspected PFAA precursors in the

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second groundwater underwent transformation via a pathway different than that of the

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first groundwater.

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Introduction Groundwater impacted with poly- and perfluoroalkyl substances (PFASs) originating

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from fire fighting activities where aqueous film forming foams (AFFFs) were used has

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become a major environmental concern and challenge. Several studies have noted the

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impacts to groundwater that likely occurred as a result of these fire fighting activities (1,

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2). Perfluoroalkyl acids (PFAAs) are among the most troublesome compounds observed

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in these impacted groundwaters, as PFAAs are recalcitrant to natural biotic and abiotic

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transformation processes. Of these PFAAs, perfluorooctanoic acid (PFOA) and

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perfluorooctane sulfonate (PFOS) have a health advisory level prescribed by the United

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States Environmental Protection Agency (USEPA) of 0.07 µg/L, both individually and

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combined (3). PFOS and PFOA have been detected in groundwater at concentrations that

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are orders of magnitude above this health advisory level (2, 4, 5).

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Electrochemical treatment of PFOA and PFOS, as well as longer and shorter-chained

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PFAAs, has shown promise. Electrochemical studies on the treatment of PFAAs typically

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have focused on using either mixed metal oxide (MMO) (6-8) or boron-doped diamond

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(BDD) anodes (9-12), where oxidative treatment in electrolyte solutions amended with

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PFOA, PFOS, or a mixture of PFAAs has been demonstrated. Transformation products

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including shorter-chained perfluorinated carboxylic acids (PFCAs) and fluoride have

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been observed, and detailed transformation mechanisms regarding the PFAAs involving

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an “unzipping” process have been proposed (9, 10, 13).

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Only a relatively few electrochemical studies involving PFAAs in natural

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groundwater systems, and in the presence of the full range of PFASs typically associated

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with AFFF-impacted waters, have been performed. One study compared the

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defluorination kinetics of PFOS and PFOA during electrical treatment using a BDD

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anode in both electrolyte and natural groundwater matrices (12). Results of this study

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showed that natural groundwater constituents had only minimal impacts on PFOA and

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PFOS treatment. However, AFFF-impacted waters typically contain a wide range of

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polyfluorinated compounds that are susceptible to oxidative transformation to PFAAs

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(14); electrochemical treatment of these PFAA precursors was not performed in this

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previous study.

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Only a very limited assessment of PFAA precursors associated with AFFF-impacted

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groundwater has been performed during electrochemical treatment. Electrochemical

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treatment of AFFF-impacted groundwater using a BDD anode was recently performed

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(15), but only PFAAs and 6:2 fluorotelomer sulfonate were evaluated, and reaction

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kinetics were not assessed in the groundwater. In another study, electrochemical

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treatment of PFAAs, along with PFAA precursors 6:2 fluorotelomer sulfonamide alkyl

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betaine, 6:2 fluorotelomer sulfonamide propyl N,N dimethylamine, and 6:2 fluorotelomer

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sulfonate, were evaluated in effluent collected from a wastewater treatment plant (16).

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Electrochemical oxidation of the precursors resulted in transient formation of PFCAs.

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While this study provided useful insight into the electrochemical oxidation pathways, the

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PFASs in the wastewater treatment plant effluent were significantly different from those

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encountered in AFFF-impacted groundwater. Perfluorinated sulfonates, perfluoroalkyl

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sulfonamide amines, and perfluoroalkyl sulfonamide amino carboxylates, which (in

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addition to PFCAs) are present in AFFF formulations manufactured by 3M (4), were not

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part of the study. Thus, the impacts of PFAA precursors associated with AFFF on

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electrochemical treatment remain unclear, and the potential transformation pathways of

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these precursor compounds have not been reported. Proper assessment of electrochemical

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approaches for treatment of AFFF-impacted waters will require a more comprehensive

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assessment of PFAA precursors, as these precursors may be present in greater quantities

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than the PFAAs (14).

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The overall goal of this study was to assess the transformation of PFAA precursors

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present in AFFF during electrochemical treatment. Specifically, potential PFAA

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precursor transformation mechanisms and rates were determined, and the impacts of the

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precursors on the overall treatment of PFAAs (including PFOS and PFOA) were assessed.

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Two AFFF-impacted waters also were assessed to examine the potential impacts of

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“fresh” versus “aged” AFFF constituents. Findings from this work highlight the

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importance of considering PFAA precursor fate when designing electrochemical

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treatment for AFFF-impacted waters.

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Experimental

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Materials

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PFOA (96% purity) was purchased from Sigma Aldrich. Two natural groundwaters,

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designated W1 and W2, were used for all the electrochemical experiments. W1 was

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collected from a facility with no known AFFF impacts, while W2 was collected from a

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US Department of Defense facility in the vicinity of a fire training area where AFFF was

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used; 3M AFFF was likely one of the products used at this location, as suggested by an

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empty drum of this solution identified at the site. Basic water quality parameters and

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dominant PFAA levels (in the case of W1, after spiking with 3M AFFF) are provided in

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Table 1. The AFFF solution used for spiking W1 was manufactured by 3M (2001), and

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was previously characterized and provided by Dr. Jennifer Field as (4).

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Electrochemical System

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Electrochemical experiments were performed similarly to those described previously (12)

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using a single compartment Microflow Cell (ElectroCell North America, Inc.). The

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cathode material was stainless steel, and the anode material was boron-doped diamond on

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niobium support (Condias, GmbH, Germany). The active surface area of each electrode

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was 10 cm2. The distance between electrodes was 4 mm.

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All experiments were performed in batch mode, where a polypropylene vessel

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served as the groundwater reservoir (Figure S1). Groundwater (0.25 L) was recirculated

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through the electrochemical cell at 0.10 L/min using a peristaltic pump. Flow rates were

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verified using a flowmeter. All experiments were performed under constant current

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conditions, while monitoring voltage. Power was supplied using an E3633A 200W power

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supply (Agilent). Current densities of 0 (no current controls) and 25 mA/cm2 were used;

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one additional test at a current density of 200 mA/cm2 also was used. All experiments

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were performed at room temperature (approximately 25 degrees C).

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For experiments performed using groundwater W1, the groundwater was amended

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with Na2SO4 so that the sulfate concentration in the groundwater increased by 500 mg/L

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sulfate. This sulfate addition was performed to increase the conductivity of the water so

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that the desired current density could be attained at an applied voltage similar to that in

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the W2 electrochemical experiments. In addition, as mentioned above, W1 was amended

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with 3M AFFF solution (0.02 mL AFFF solution to 250 mL of W1 groundwater). Thus,

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the AFFF-spiked W1 groundwater served as the “fresh” AFFF-impacted groundwater,

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while the W2 groundwater served as the “aged” AFFF-impacted groundwater. All

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groundwater was passed through a 20 µm filter prior to initiating the electrochemical

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experiments to prevent any particulates from entering the electrochemical cell.

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The groundwater solution in each experiment was monitored as a function of time

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throughout the duration of each experiment, which typically lasted 8 hours. Samples were

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collected for determination of pH, anions, and PFASs. Temperature of the recirculated

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groundwater also was monitored.

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Initially, duplicate samples were collected at select timepoints and immediately

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quenched by mixing with 20 µl of a sterile 1.5 g/L sodium thiosulfate solution to

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scavenge any residual oxidant species remaining in the sample (17). Preliminary tests

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(data not shown) indicated that addition of the quenching agent did not impact the levels

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of PFASs detected in the electrochemically treated samples, so this preservation step was

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discontinued in later experiments. Control experiments were also performed without

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applied current to account for any PFAS losses, such as sorption or volatilization, not

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attributable to electrochemical treatment.

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An additional experiment was performed in duplicate using PFOA (initial

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concentration of 20 mg/L) in 150 cm3 of 1480 mg/L sodium sulfate; the current density

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was 25 mA/cm2. This PFOA experiment was used to serve as a comparison to PFOA

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transformation rates in the more complex W1 and W2 groundwater systems, which

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contained a mixture of PFASs.

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Analytical Methods

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An Oakton probe (Part no. WD-35634-14) was used to measure sample pH. Anions

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were analyzed via ion chromatography using EPA Method 300.0, and perchlorate was

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analyzed via ion chromatography using EPA Method 314.2. The detection limit for

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anions (except perchlorate) was 200 µg/L; the detection limit for perchlorate was 0.25

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µg/L. Descriptions of the quantitative analyses for PFAAs and the semi-quantitative

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analyses for potential PFAA precursors are provided in the Supporting Information. Total

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oxidizable precursor analysis, based on the previously developed methods (14), were

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performed on W1 and W2 by SGS Axys Analytical Services Ltd. (BC, Canada).

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Results and Discussion

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PFAS Composition of W1 and W2

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Levels of PFAAs in W1 and W2 are provided in Table 1. The remaining dominant

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fluorinated compounds (>106 area counts) present in W1 and W2 prior to electrochemical

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treatment (t=0 timepoint in the batch experiments), based on high resolution mass

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spectrometry (HRMS), are summarized in Tables S1 and S2, respectively. Tables S1 and

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S2 also include compounds that showed transient increases during electrochemical

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treatment; confidence levels and similarity scores for these compounds are provided in

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Tables S3 and S4. For W1, consistent with analysis of 3M AFFF performed previously

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(4), several classes of sulfonamido compounds with perfluorinated tails were detected in

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the AFFF-spiked groundwater. Perfluorinated chain lengths of n= 4 through 6 typically

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were the dominant species. However, perfluorooctane sulfonamide (n=8), a potential

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precursor of PFOA and/or PFOS (14,18), was identified. The presence of both

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perfluoroalkane sulfonamides (FASAs) and perfluoroalkane sulfinates (PFASis) indicate

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that previously identified PFAA precursors are present in the AFFF-spiked W1 (19, 20).

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The compounds identified in W2 were similar in structure to those identified in W1.

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However, compounds containing the sulfonated end groups of the non-fluorinated

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branches (e.g., S-OHPrAmPr-FQASA-OHPrS) detected in W2 were not detected in W1.

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Perfluorinated chain lengths of n=4 through 6 were the dominant species for these

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sulfonated sulfonamides. As with W1, FASAs (known PFAA precursors (14, 18)), were

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also present in W2. For n=5 and 6, FASA levels (based on integrated area counts) were

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10- to 100-times less than in W1. For n=4 and 8, FASA levels were similar (within a

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factor of 2) for both W1 and W2. These n=8 FASA levels, as well as the presence of n=8

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compounds for both N-SPAmP-FASA and PFASA-PDA, suggest that W2 has similar or

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greater potential for formation of PFOA or PFOS from oxidative transformation of

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precursors as does W1. W2 did not contain any detectable PFASi’s, another known class

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of PFAA precursors (19).

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To further assess the potential for precursor transformation to PFAAs, Figure S2

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shows the baseline (prior to electrochemical treatment) fluorine content based on

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integrated area response for all the precursors (n=4 through 8) present in W1 and W2.

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Figure S2 shows that the fluorine content in potential precursor compounds in W2 were

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approximately 5-times greater than in W1, which again suggests that W2 has equal or

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greater likelihood of forming PFAAs upon electrochemical oxidation. However, the

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response factors for the potential precursors in W1 and W2 may vary considerably for

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each compound, thus the information provided in Figure S2 may not be an appropriate

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indicator of potential PFAA formation via oxidation (although, considering the structural

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similarity of the compounds, the data in Figure S2 is expected to provide an order of

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magnitude type estimate).

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Oxidative transformation of PFAA precursors also was assessed using the total

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oxidizable precursor (TOP) assay (14). Results are provided for both W1 and W2 in

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Figure S3. Despite the apparent abundance of potential precursor compounds present in

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W2 relative to W1, the TOP assay indicates that the PFAA precursors present in W2 are

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negligible compared to W1, as PFCAs increased approximately 200-times in W1 during

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the TOP assay. These results suggest that PFAA formation via oxidation likely originates

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from CEtAmPr-FASA-PrAs, AmPr-FASA-PrAs, and FASAs that are present only in W1

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(or, present in much greater quantities in W1 than in W2). It is plausible that these

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compounds were originally present in the AFFF source materials associated with W2, but

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were transformed in situ prior to collecting the W2 groundwater.

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Interestingly, AmPr-FASA and the other potential precursor compounds present in

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W2 (Figure S2) do not appear to substantially contribute to PFAA formation via chemical

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oxidation. This could be due to their oxidation pathway, or due to the fact that their

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concentrations are too low to measurably contribute to the PFAA mass already present in

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W2. This will be further explored in subsequent sections as PFAA formation and the

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fluoride balance are assessed during electrochemical treatment.

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PFAS Transformations during Electrochemical Treatment – W1

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Electrochemical treatment at 25 mA/cm2 required an applied voltage of

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approximately 13 V and 16 V for W1 and W2, respectively. A small increase in

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temperature from approximately 25 to 30 degrees C occurred during treatment. The pH

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for both waters remained circumneutral.

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The PFASs shown in Tables S1 and S2 for W1 and W2 were generally removed

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during electrochemical treatment. Figure S4 shows the decreases in CEtAMPr-FASA-

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PrAs, AmPr-FASA-PrAs, and AmPr-FASAs for W1. Figure S5 shows the transient

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increases in OAmPr-FASAs, MeFASAAs, FASAs, and PFASi’s for W1; these

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compounds all show an increase followed by a decrease. It is important to note that

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potential precursor levels analyzed via HRMS were determined without stable isotope

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internal standards, so results should be interpreted with caution.

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Electrochemical treatment of W1 also showed transient increases in PFCAs, but not

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corresponding increases in the perfluorinated sulfonic acids (PFSAs), as shown in Figure

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1. These results are consistent with the TOP assay (Figure S3), as well as the data of

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Houtz and Sedlak (14). Finally, fluoride generation was observed (Figure S6).

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Collectively, these data suggest that oxidative electrochemical treatment of the PFASs in

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W1 (including many of the precursors included in the 3M AFFF) proceeds through initial

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oxidation steps (Figure 2) that include a combination of oxidation of the terminal amine,

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dealkylation of the sulfonamide, and defluorination of the carbon chain. The pathway

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shown in Figure 2 assumes that the branched sulfonamide structures (CEtAMPr-FASA-

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PrAs and AmPr-FASA-PrAs,) oxidatively transform yielding OAmPr-FASAs, which are

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then rapidly oxidized as shown. It is speculated that a currently unidentified precursor(s)

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results in the formation of MeFASAAs. All the intermediate species shown in Figure 2

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showed transient increases during electrochemical treatment.

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Previously proposed pathways for the aerobic biotransformation of

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ethylperfluorooctane sulfonamide have indicated that formation of OAmPr-FASAs

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preceeds the formation of FASAs (18, 19), thus the formation of OAmPr-FASAs

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observed herein is consistent with the oxidative formation of FASAs. Mejia-Avendaño et

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al. (20) have shown the formation of FASA from AmPr-FASAs. The formation of FASAi

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from FASAs also has been observed during aerobic biotransformation processes (19).

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However, the formation of PFCAs from sulfonamido precursors has only been observed

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through abiotic pathways (14, 21), and not biotic pathways (18, 19). Houtz and Sedlak

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(14) also have shown that abiotic oxidation of both MeFASAAs and FASAs results in the

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formation of PFCAs, which is consistent with the oxidation pathway shown in Figure 2.

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Electrochemical oxidation of non-fluorine containing sulfonamides, with cleavage of the

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S-N bond, has been previously demonstrated (22). The unzipping and defluorination of

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PFAAs via electrochemical approaches have been well documented (23).

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Electrochemical dealkylation and amine oxidation for non-fluorine containing

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compounds also have been well documented (24, 25).

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In W1, the generation of the n=7 and n=8 PFCAs is much less than that of the

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shorter-chained PFCAs (Figure 1). This is likely due to the relative abundance of n=4 to

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6 precursors present and/or the transformation of the longer (7 and 8 chain) PFCAs to

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shorter chain PFCAs. The only n=8 precursor identified in W1 was perfluorooctane

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sulfonamide (FOSA), and no n=7 precursors were identified. The generation of PFHpA

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likely was due to the electrochemical oxidation of PFOA (6). These results are consistent

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with those observed by Houtz et al. (26), who observed substantial increases in n=4

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through 6 PFCAs due to chemical oxidation of 3M AFFF, but no reported increases in

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n=7 or 8 PFCAs. It is also possible that the small increase in PFHpA observed herein was

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due to an unidentified precursor present in the dissolved AFFF solution.

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PFAS Transformations during Electrochemical Treatment – W2 Figure S7 shows the decreases in S-OHPrAmPr-FASA-OHPrS, SPrAmPr-

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FASAPrS,S-OHPrAmPr-FASAA, SPrAmPr-FASAA, SPrAmPr-FASA, SPr-FASA, and

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AmPr-FASA for W2. Figure S8 shows the transient increases in FASAs (n=4 and n=6)

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and K-PFASs (n=2,3,4,6) for W2. The transiently generated FASA levels for n=4 and 6

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were 10- to 100-times less than those for W1, and K-PFAS area counts were generally 3-

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to 10-times less than FASA area counts. Unlike W1, W2 showed no transient increases in

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OAmPr-FASA, MeFASAAs, or PFASi’s; W2 also showed no transient increases in

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PFCAs or PFSAs (Figure 3), but did yield fluoride in quantity similar to that observed for

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W1 (Figure S6). An additional experiment was performed at a lower current density (15

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mA/cm2), and with sampling at 1 and 2 hours to ensure that a large transient increase in

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PFAAs did not occur at early timepoints (t