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Legacy and Emerging Perfluoroalkyl Substances Are Important
Drinking Water Contaminants in the Cape Fear River Watershed of
North Carolina
Mei Sun,*'t't` Elisa Arevalo,* Mark Strynar,§ Andrew Lindstrom,§ -Michael Richardson," Ben Kearns,"
Adam Pickett,' Chris Smith,# and Dedef R. U. Knappe$
'Department of Civil and Environmental Engineering, University of North Carolina at Charlotte, Charlotte, North Carolina 28223,
United States
*Department of Civil, Construction, and Environmental Engineering, North Carolina State University, Raleigh, North Carolina
27695, United States
§National Exposure Research Laboratory, U.S. Environmental Protection Agency Research, Triangle Park, North Carolina 27711,
United States
IlCape Fear Public Utility Authority, Wilmington, North Carolina 28403, United States
-LTovirn of Pittsboro, Pittsboro, North Carolina 27312, United States
#Fayetteville Public Works Commission, Fayetteville, North Carolina 28301, United States
® Supporting Information
ABSTRACT: Long -chain per- and polyfluoroalkyl substances Point 8,gym" A
(PFASs) _ are being replaced by short -chain PFASs and non -point " ` A
fluorinated alternatives. For ten legacy PFASs and seven sources B 1 PFPrOPrA ("GenX")
recently discovered perfluoroalkyl ether carboxylic acids - c
(PFECAs), we report (1) their occurrence in the Cape Fear 0 200 400 600 800
River (CFR) watershed, (2) their fate in water treatment F F PFAS concentration (ng/L)
processes, and (3) their adsorbability on powdered activated F F F F 7�O Qg
carbon (PAC). In the headwater region of the CFR basin, /
PFECAs were not detected in raw water of a drinking water FO OH Fluorochemical�
treatment plant (DWTP), but concentrations of legacy PFASs F F F Manufacturer
PFPrOPrA ("GenX") C `
were high. The U.S. Environmental Protection Agency's•
lifetime health advisory level (70 ng/L) for perfluorooctane-
sulfonic acid and perfluorooctanoic acid (PFOA) was exceeded on 57 of 127 sampling days. In raw water of a DWTP
downstream of a PFAS manufacturer, the mean concentration of perfluoro-2-propoxypropanoic acid (PFPrOPrA), a replacement
for PFOA, was 631 ng/L (n = 37). Six other PFECAs were detected, with three exhibiting chromatographic peak areas up to 15
times that of PFPrOPrA. At this DWTP, PFECA removal by coagulation, ozonation, biofiltration, and disinfection was negligible.
The adsorbability of PFASs on PAC increased with increasing chain length. Replacing one CFZ group with an ether oxygen
decreased the affinity of PFASs for PAC, while replacing additional CF2 groups did not lead to further affinity changes.
N INTRODUCTION
Per- and polyfluoroalkyl substances (PFASs) are extensively
used in the production of plastics, - water/stain repellents,
firefighting foams, and food -contact paper coatings. The
widespread occurrence of PFASs in drinking water sources is
closely related to the presence of sources such as industrial
sites, military fire training areas, civilian airports, and waste-
water treatment plants.' Until 2000, long -chain perfluoroalkyl
sulfonic acids [C Fz +1S03H; n > 6 (PFSAs)] and perfluoro-
alkyl carboxylic acids [C FZn+1COOH; n >_ 7 (PFCAs)] were
predominantly used? Accumulating evidence about the
ecological persistence and human health effects associated
with exposure to long -chain PFASs3'4 has led to an increased
level of regulatory attention. Recently, the U.S. Environmental
Protection Agency (USEPA) established a lifetime health
• ACS Publications m XXXX American Chemical Society
advisory level (HAL) of 70 ng/L for the sum of
perfluorooctanoic acid (PFOA) and perfluorooctanesulfonic
acid (PFOS) concentrations in drinking water.5'6 Over the past
decade, production of long -chain PFASs has declined in Europe
and North America, and manufacturers are moving toward
short -chain PFASs and fluorinated alternatives, 7-10 Some
fluorinated alternatives were recently identified,""' but others
remain unknown12-14 because they are either proprietary or
manufacturing byproducts.
Received:
October 13, 2016
Revised:
November 8, 2016
Accepted:
November 10, 2016
Published:
November 10, 2016
DOL 10.1021/acs.estlett.6b00398
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One group of fluorinated alternatives, perfluoroalkyl ether
carboxylic acids (PFECAs), was recently discovered in the Cape
Fear River (CFR) downstream of a PFAS manufacturing
facility." Identified PFECAs included perfluoro-2-methoxy-
acetic acid (PFMOAA), perfluoro-3-methoxypropanoic acid
(PFMOPrA), perfluoro-4-methoxybutanoic acid (PFMOBA),
perfluoro-2-propoxypropanoic acid (PFPrOPrA), perfluoro-
(3,5-dioxahexanoic) acid (PF02HxA), perfluoro(3,5,7-trioxa-
octanoic) acid (PF030A), and perfluoro(3,5,7,9-tetraoxadeca-
noic) acid (PF04DA) (Table S1 and Figure S1). The
ammonium salt of PFPrOPrA is a known PFOA alternativels
that has been produced since 2010 with the trade name
"GenX7. To the best of our knowledge, the only other
published PFECA occurrence data are for PFPrOPrA in Europe
and China,15 and no published data about the fate of PFECAs
during water treatment are available. Except for a few studies
(most by the manufacturer),16-20 little is known about the
toxicity, pharmacokinetic behavior, or environmental fate and
transport of PFECAs.
The strong C-F bond makes PFASs refractory to abiotic and
biotic degradation,21 and most water treatment processes are
ineffective for legacy PFAS removal.22-27 Processes capable of
removin PFCAs and PFSAs include nanofiltration,28 reverse
osmosis, 5 ton exchange,28,29 and activated carbon adsorp-
tion,2829 with activated carbon adsorption being the most
widely employed treatment option.
The objectives of this research were (1) to identify and
quantify the presence .of legacy PFASs and emerging PFECAs
in drinking water sources, (2) to assess PFAS removal by
conventional and advanced processes in a full-scale drinking
water treatment plant (DWTP), and (3) to evaluate the
adsorbability of PFASs on powdered activated carbon (PAC).
0 MATERIALS AND METHODS
Water Samples. Source water of three DWTPs treating
surface water in the CFR watershed was sampled between June
14 and December 2, 2013 (Figure S2). Samples were collected
from the raw water _tap at each DWTP daily as either 8 It
composites (DWTP A, 127 samples) or 24 h composites
(DWTPP B, 73 samples; DWTP C, 34 samples). Samples were
collected_ in 250 mL HDPE bottles and picked up (DWTPs A
and B) or shipped overnight (DWTP C) on a weekly basis. All
samples were stored at room temperature until they were
analyzed (within 1 week of receipt). PFAS losses during storage
were negligible on the basis of results of a 70 day holding study
at room tempera [D, /+ gush -�D 14, grab samples were
collected at DWTAC er each unit process in the treatment
train [raw water ozon "on, coagulation/flocculation/sedimen-
tation, settled water ozonation, biological activated carbon
(BAC) filtration, and disinfection by medium -pressure UV
lamps and free chlorine]. Operational conditions of DWTP C
on the sampling day are listed in Table S2. Samples were
collected in 1 L HDPE bottles and stored at room temperature
until they were analyzed. On the same day, grab samples of
CFR water were collected in six 20 L HDPE carboys at William
0. Huske Lock and Dam downstream of a PFAS manufacturing
site and stored at 4 °C until use in PAC adsorption experiments
(background water matrix characteristics listed in Table S3).
Adsorption Experiments. Adsorption of PFASs by PAC
was studied in batch reactors (amber glass bottles, 0.45 L of
CFR water). PFECA adsorption was studied at ambient
concentrations (-1000 ng/L PFPrOPrA, chromatographic
peak areas of other PFECAs being approximately 10-800%
of the PFPrOPrA area). Legacy PFASs were present at low
concentrations (<40 ng/L) and spiked into CFR water at
-1000 ng/L each. Data from spiked and nonspiked experi-
ments showed that the added legacy PFASs and methanol (1
ppmr,) from the primary stock solution did not affect native
PFECA removal. A thermally activated, wood -based PAC
(PicaHydro MP23, PICA USA, Columbus, OH; mean diameter
of 12 ym, BET surface area of 1460 m2/�)30 proven to be
effective for PFAS removal in a prior study was used at doses
of 30, 60, and 100 mg/L. 'These doses represent the upper
feasible end for drinking water treatment. Samples were taken
prior to and periodically after PAC addition for PFAS analysis.
PFAS losses in PAC -free blanks were negligible.
PFAS Analysis. Information about analytical standards and
liquid chromatography -tandem mass spectrometry (LC -MS/
MS) methods for PFAS quantification is provided in the
Supporting Information.
■ RESULTS AND DISCUSSION
Occurrence of PFASs in Drinking Water Sources. Mean
PFAS concentrations in source water of three DWTPs treating
surface water from the CFR watershed are shown in Figure 1.
PFBA ■ PFPeA - PFHxA PFHpA n PFOA : PFNA
PFDA ■ PFBS a PFHxS ■ PFOS ■ PFPrOPrA
n=127
Community
n=73
Community C
n=34
0 200 400 600 ODD
Average concentration in drinking watersource (nglL)
Figure 1. Occurrence of PPASs at drinking water intakes in the CFR
watershed. Concentrations represent averages of samples collected
between June and December 2013. Individual samples with
concentrations below the quantitation limits (QLs) were considered
as 0 when calculating averages, and average concentrations below the
QLs were not plotted.
In communities A and B, only legacy PFASs were detected
(mean TPFAS of 355 ng/L in community A and 62 ng/L in
community B). Detailed concentration data are shown in Table
S6 and Figure S3. In community A, PFCAs with four to eight
total carbons, perfluorohexanesulfonic acid (PFHxS), and
PFOS were detected at mean concentrations above the
quantitation limits (QLs). During the 127 day sampling
campaign, the sum concentration of PFOA and PFOS exceeded
the USEPA HAL of 70 ng/L on 57 days. The mean sum
concentration of PFOA and PFOS over the entire study period
was 90 ng/L, with approximately equal contributions from
PFOS (44 ng/L) and PFOA (46 ng/L). Maximum PFOS and
PFOA concentrations were 346 and 137 ng/L, respectively.
Similar PFOS and PFOA concentrations were observed in the
same area in 2006,31 suggesting that PFAS source(s) upstream
of community A have continued negative impacts on drinking
water quality. Also, our data show that legacy PFASs remain as
surface water contaminants of concern even though their
production was recently phased out in the United States. It is
important to note, however, that among the PFCAs that were
measured in both 2006 and 2013 (PFHxA to PFDA), the
PFCA speciation shifted from long -chain (-80-85%
C„F2n+1COOH; n = 7-9) in 2006 to short -chain (76%
C„F2„+1COOH; n = 5-6) in 2013. In contrast, the PFSA
speciation was dominated by PFOS in both 2006 and 2013.
DOh 10.1021/acs.estlem6b00398
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Relating total PFAS concentration to average daily streamflow
(Figure S4) illustrated a general trend of low PFAS
concentrations at high flow, and high concentrations at low
flow, consistent with the hypothesis of one or more upstream
point sources.
In community B, perfluorobutanoic acid (PFBA) and
perfluoropentanoic acid (PFPeA) were most frequently
detected with mean concentrations of 12 and 19 ng/L,
respectively. Mean PFOA and PFOS concentrations were
below the QLs, and the maximum sum concentration of PFOA
and PFOS was 59 ng/L. Lower PFAS concentrations in
community B relative to community A can be explained by the
absence of substantive PFAS sources between the two
communities, dilution by tributaries, and the buffering effect
of Jordan Lake, a large reservoir located between communities
Aand B.
In community C (downstream of a PFAS manufacturing
site), only mean concentrations of PFBA and PFPeA were
above the QLs. The relatively low concentrations of legacy
PFASs in the finished drinking water of community C are
consistent with results from the USEPA's third unregulated
contaminant monitoring rule for this DWTP 32 However, high
concentrations of PFPrOPrA were detected (up to —4500 ng/
L). The average PFPrOPrA concentration (631 ng/L) was
approximately 8 times the average summed PFCA and PFSA
concentrations (79 ng/L). Other PFECAs had not yet been
identified at the time of analysis. Similar to communities A and
B, the highest PFAS concentrations for community C were also
observed at low flow (Figure S4). Stream flow data were used
in conjunction with PFPrOPrA concentration data to
determine PFPrOPrA mass fluxes at the intake of DWTP C.
Daily PFPrOPrA mass fluxes ranged from 0.6 to 24 kg/day with
a mean of 5.9 kg/day.
Fate of PFASs in Conventional and Advanced Water
Treatment Processes. To investigate whether PFASs can be
removed from impacted source water, samples from DWTP C
were collected at the intake and after each treatment step.
Results in Figure 2 suggest conventional and advanced
treatment processes (coagulation/flocculation/sedimentation,
raw and settled water ozonation, BAC filtration, and
disinfection by medium -pressure UV lamps and free chlorine)
did not remove legacy PFASs, consistent with previous
studies.22-26 The data further illustrate that no measurable
PFECA removal occurred in this DWTP. Concentrations of
some PFCAs, PFSAs, PFMOPrA, PFPrOPrA, and PFMOAA
may have increased after ozonation, possibly because of the
oxidation of precursor compounds25 Disinfection with
medium -pressure UV lamps and free chlorine (located between
the BAC effluent and the finished water) may have decreased
concentrations of PFMOAA, PFMOPrA, PFMOBA, and
PFPrOPrA, but only to a limited extent. Small concentration
changes between treatment processes may also be related to
temporal changes in source water PFAS concentrations that
occurred in the time frame corresponding to the hydraulic
residence time of the DWTP.
Results in Figure 2 further illustrate that the PFAS signature
of the August 2014 samples was similar to the mean PFAS
signature observed during the 2013 sampling campaigns shown
in Figure 1; i.e., PFPrOPrA concentrations (400-500 ng/L)
greatly exceeded legacy PFAS concentrations. Moreover, three
PFECAs (PFMOAA, PF02HxA, and PF03OA) exhibited peak
areas 2-113 times greater than that of PFPrOPrA (Figure 2b).
(a) Ratty water
Pre ozone effluent
Settled water
Settled -ozone effluent
BAC effluent
Finished water
0 100 200 300 400 500 600 700 800
Concentration of traditional PFASs
(J'71 at a WTP in Community C (ng/L)
■ PFPrOPrA PFBA ■ PFPeA .: PFHXA PFHpA to PFOA
s pflA-'F PFDA ■ PFBS to PFHS ■ PFOS
(b) Raw water
Pre -ozone effluent
Settled water
Settled -ozone effluent
BAC effluent
Finished water
1
II
I -
I
I _
0 50,000 100,000 150,000 200,000 1-50,000 300,000
Peak area counts of emerging PFASs
at WTP in Community
■ PFPrOPrA - PFMOAA c PFMOPrA a PFMOBA
PF02HxA-PF030A PF04DA
Figure 2. Fate of (a) legacy PFASs and PFPrOPrA and (b) PFECAs
through a full-scale water treatment plant. Because authentic standards
were not available for PFECAs other than PFPrOPrA, chromato-
graphic peak area counts are shown in panel b. PFPrOPrA data are
shown in both panels and highlighted with dashed ovals for reference.
Compounds with concentrations below the QLs were not plotted.
The existence of high levels of emerging PFASs suggests a need
for their incorporation into routine monitoring.
Adsorption of PFASs by PAC. PAC can effectively remove
long -chain PFCAs and PFSAs, but its effectiveness decreases
with decreasing PFAS chain length.11,15,19 It is unclear,
however, how the presence of ether group(s) in PFECAs
impacts adsorbability. After a contact time of 1 h, a PAC dose
of 100 mg/L achieved >80% removal of legacy PFCAs with
total carbon chain lengths of >7. At the same PAC dose,
removals were 95% for PF04DA and 5496 for PF030A, but
<40% for other PFECAs. Detailed removal percentage data as a
function of PAC contact time are shown in Figure S5. There
was no meaningful removal of PFMOBA or PFMOPrA, and the
variability shown in Figure SS is most likely associated with
analytical variability. PFMOAA could not be quantified by the
analytical method used for these experiments; however, on the
basis of the observations that PFAS adsorption decreases with
decreasing carbon chain length and that PFECAs with one or
two more carbon atoms than PFMOAA (i.e., PFMOPrA and
PFMOBA) exhibited negligible removal (Figure 3), it is
expected that PFMOAA adsorption is also negligible under
the tested conditions.
To compare the affinity of different PFASs for PAC, PFAS
removal percentages were plotted as a function of PFAS chain
length [the sum of carbon (including branched), ether oxygen,
and sulfur atoms] (Figure 3b). The adsorbability of both legacy
and emerging PFASs increased with increasing chain length.
PFSAs were more readily removed than PFCAs of matching
chain length, a result that agrees with those of previous
c DM 10.1021 lacs.estletL61aW398
Environ. Sci. Technol. Lett. XXXX, XXX, XXX-XXX
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100%
80%
-20%
< j z o < < < < _< < x < < d z G
C- O G G N ni C L• C
o = 0 c G L o
L' L L• L .. —
C G
PFCAs Mono-etherPFECAs Mulu-etherPFECAs PFSAs
a
10046
60%
0.
% 40°0
r.
0 20%
O '0
� 0 046
M -20%
4
� 3 5 7 9 it
Chain length
-*--PFCAs ---Mono-ether PFECAs --m—Multi-ether PFECAs - PFSAs
Figure 3. PFAS adsorption on PAC (a) at carbon doses of 30, 60, and 100 mg/L and (b) as a function of PFAS chain length. The PAC contact time
in CFR water was 1 h. Legacy PFASs were spiked at —1000 ng/L, and the emerging PFASs were at ambient concentrations. Figures show average
PFAS removal percentages, and error bars show one standard deviation of replicate experiments.
studies."""' PFECAs exhibited adsorbabilities lower than
those of PFCAs of the same chain length (e.g., PFMOBA <
PFHxA), suggesting that the replacement of a CFZ group with
an ether oxygen atom decreases the affinity of PFASs for PAC.
However, the replacement of additional CFZ groups with ether
groups resulted in small or negligible affinity changes among
the studied PFECAs (e.g., PFMOBA N PF02HxA, PFPrOPrA
— PF030A). Alternatively, if only the number of perfluorinated
carbons were considered as a basis of comparing adsorbability,
the interpretation would be different. In that case, with the
same number of perfluorinated carbons, PFCAs have an affinity
for PAC higher than that of monoether PFECAs (e.g., PFPe-A >
PFMOBA) but an affinity- lower than that of multi -ether
PFECAs (e.g., PFPeA < PF030A).
To the best of our knowledge, this is the first paper reporting
the behavior of recently identified PFECAs in water treatment
processes. We show that PFECAs dominated the PFAS
signature in a drinking water source downstream of a
fluorochemical manufacturer and that PFECA removal by
many conventional and advanced treatment processes was
negligible. Our adsorption data further show that PFPrOPrA
("GenX") is less adsorbable than PFOA, which it is replacing.
Thus, PFPrOPrA presents a greater drinking water treatment
challenge than PFOA does. The detection of potentially high
levels of PFECAs, the continued presence of high levels of
legacy PFASs, and the difficulty of effectively removing legacy
PFASs and PFECAs with many water treatment processes
suggest the need for broader discharge control and contaminant
monitoring.
0 ASSOCIATED CONTENT
® Supporting Information
The Supporting Information is available free of charge on the
ACS Publications website at DOI: 10.1021/acs.estlett.6b00398.
Six tables, five figures, information about PFASs,
analytical methods, and detailed results (PDF)
N AUTHOR INFORMATION
Corresponding Author
*E-mail. msun8@uncc.edu. Phone: 704-687-1723.
ORCID
Mei Sun: 0000-0001-5854-9862
Notes
The views expressed in this article are those of the authors and
do not necessarily represent the views or policies of the
USEPA
The authors declare no competing financial interest.
® ACKNOWLEDGMENTS
This research was supported by the National Science
Foundation (Grant 1550222), the Water Research Foundation
(Project 4344), and the North Carolina Urban Water
Consortium.
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fate of perfluoroalkyl and polyfluoroalkyl substances (PFASs) in
drinking water treatment: A review. Water Res. 2014, 50, 318-340.
(26) Appleman, T. D.; Higgins, C. P.; Quinones, 0.; Vanderford, B.
J.; Kolstad, C.; Zeigler-Holady, J. C.; Dickenson, E. R V. Treatment of
poly- and perfluoroalkyl substances in U.S. full-scale water treatment
systems. Water Res. 2014, 51, 246-255.
(27) Merino, N.; Qu, Y.; Deeb, R A, Hawley, E. L.; Hoffmann, M.
R; Mahendra, S. Degradation and removal methods for perfluoroalkyl
and polyfluoroalkyl substances in water. Environ. Eng. Sci. 2016, 33 (9),
615-649.
(28) Appleman, T. D.; Dickenson, E. R V.; Bellona, C.; Higgins, C.
P. Nanofiltration and granular activated carbon treatment of
perfluoroalkyl acids. J. Hazard. Mater. 2013, 260, 740-746.
(29) Dudley, L. A.; Arevalo, E. C.; Knappe, D. R U. Removal of
p4uoroalkyl substances by PAC adsorption and anion exchange; Water
Research Foundation: Denver, 2015.
(30) Dunn, S. E.; Knappe, D. R. U. Disinfection by-product precursor
and micropollutant removal by powdered activated carbon; Water
Research Foundation: Denver, 2013.
(31) Nakayama, S.; Strynar, M. J.; Helfant, L.; Egeghy, P.; Ye, X.;
Lindstrom, A. B. Perfluorinated compounds in the Cape Fear drainage
basin in North Carolina. Environ. Sci. Technol. 2007, 41 (15), 5271-
5276.
(32) Unregulated contaminant monitoring rule 3 (UCMR 3). http://
water.epa.gov/lawsregs/rulesregs/sdwa/ucmr/ucmr3/; U.S. Environ-
mental Protection Agency: Washington, DC (accessed July 29, 2016).
E o01: 10.1021/acs.estlett.6b00398
Environ. Sci. Technol. Lett. XXXX, XXX, XXX—XXX
DEQ-CFW 00003335
Supporting information
Legacy and Emerging Perfluoroalkyl Substances Are Important
Drinking Water Contaminants in the Cape Fear River Watershed
of North Carolina
Supporting information includes analytical method description, 6 tables, and 5 figures.
Mei Sunl-2 , Elisa Areva102, Mark Strynar3, Andrew Lindstrom3, Michael Richardson4, Ben
Kearns4, Adam Pickett5, Chris Smith6, and Detlef R.U. Knappe2
'Department of Civil and Environmental Engineering
University of North Carolina at Charlotte
Charlotte, North Carolina 28223, USA
2 Department of Civil, Construction, and Environmental Engineering
North Carolina State University
Raleigh, North Carolina 27695, USA
3 National Exposure Research Laboratory
U.S. Environmental Protection Agency
Research Triangle Park, North Carolina 27711, USA
4 Cape Fear Public Utility Authority
Wilmington, North Carolina 28403, USA
5 Town of Pittsboro
Pittsboro, North Carolina 27312, USA
6 Fayetteville Public Works Commission
Fayetteville, North Carolina 28301, USA
*Corresponding Author Email: msun8@uncc.edu; Phone: 704-687-1723
Page 1 of 12
DEQ-CFW 00003336
Analytical standards: PFASs studied in this research are listed in Table S1. For legacy PFASs,
native and isotopically labeled standards were purchased from Wellington Laboratories
(Guelph, Ontario, Canada). Native PFPrOPrA was purchased from Thermo Fisher Scientific
(Waltham, MA). No analytical standards were available for other PFECAs.
PFAS quantification: PFAS concentrations in samples from DWTPs and adsorption tests were
determined by liquid chromatography tandem mass spectrometry (LC-MS/MS) using a large -
volume (0.9 mL) direct injection method. An Agilent 1100 Series LC pump and PE Sciex API
3000 LC-MS/MS system equipped with a 4.6 mm x 50 mm FIPLC column (Kinetex C18 54m
100A, Phenomenex Inc.) was used for PFAS analysis. The eluent gradient is shown in Table S4
in SI. All samples, calibration standards, and quality control samples were spiked with
isotopically labeled internal standards, filtered through 0.45-µm glass microfiber syringe filters,
and analyzed in duplicate. The MS transitions for PFAS analytes and internal standards are
shown in Table S5 in SI. The quantitation limit (QL) was 25 ng/L for PFOS and
perfluorodecanoic acid, and 10 ng/L for other legacy PFASs and PFPrOPrA. The QL was
defined as the first point of the standard curve, for which the regression equation yielded a
calculated value within ±30% error. For PFECAs without analytical standards, chromatographic
peak areas are reported.
PFAS concentrations along the treatment train of DWTP C were analyzed using a Waters
Acquity ultra performance liquid chromatograph interfaced with a Waters Quattro Premier XE
triple quadrupole mass spectrometer (Waters, Milford, MA, USA) after solid phase extraction.
Method details are described elsewhere.' The QL for all PFASs with analytical standards was
0.2 ng/L, and peak areas were recorded for PFECAs without standards.
Page 2 of 12
DEQ-CFW 00003337
Table S1. Perfluoroalkyl substances (PFASs) detected in the Cape Fear River (CFR) watershed
MolecularChain length
.m.. ' '
.. • .
Perfluorocarboxylic acids (PFCAs)
Perfluorobutanoic acid (PFBA)
214.0
C4H97O2
375-22-4
3
4
Perfluoropentanoic acid (PFPeA)
264.0
C5HF9O2
2706-90-3
4
5
Perfluorohexanoic acid (PFH)cA)
314.1
C6HF11O2
307-24-4
5
6
Perfluoroheptanoic acid (PFHpA)
364.1
C71U13O2
375-85-9
6
7
Perfluorooctanoic acid (PFOA)
414.1
CaHF15O2
335-67-1
7
8
Perfluorononanoic acid (PFNA)
464.1
C9HF17Oz
375-95-1
8
9
Perfluorodecanoic acid (PFDA)
514.1
C1oHF19Oz
335-76-2
9
10
Perfluorosulfonic acids (PFSAs)
Perfluorobutane sulfonic acid (PFBS)
300.1
C41-IF9SO3
375-73-5
4
5
Perfluorohexane sulfonic acid (PFHxS)
400.1
C61IF13SO3
355-46-4
6
7
Perfluorooctane sulfonic acid (PFOS)
500.1
C8hT17SO3
1763-23-1
8
9
Perfluoroalkyl ether carboxylic acids with one ether group (mono -ether PFECAs)
Perfluoro-2-methoxyacetic acid (PFMOAA)
180.0
CAU5O3
674-13-5
2
4
Perfluoro-3-methoxypropanoic acid (PFMOPrA)
230.0
C U7O3
377-73-1
3
5
Perfluoro-4-methoxybutanoic acid (PFMOBA)
280.0
CSHF9O3
863090-89-5
4
6
Perfluoro-2-propoxypropanoic acid (PFPrOPrA)
330.1
C61U11O3
13252-13-6
5
7
Perfluoroalkyl ether carboxylic acids with multiple ether group (multi -ether PFECAs)
Perfluoro(3,5-dioxahexanoic) acid (PFO2HxA)
246.0
CHF7O4
39492-88-1
3
6
Perfluoro(3,5,7-trioxaoctanoic) acid (PFO3OA)
312.0
CSHF9Os
39492-89-2
4
8
Perfluoro(3,5,7,9-tetraoxadecanoic) acid (PFO4DA)
378.1
C61-IF11O6
39492-90-5
5
10
Page 3of12
DEQ-CFW 00003338
Table S2.Operational conditions of DWTP C on sampling day (August 18, 2014)
Parameter
Raw water ozone dose
Value
3.1 mg/L
Raw water total organic carbon concentration
6.0 mg/L
Aluminum sulfate coagulant dose
43 mg/L
Coagulation pH
5.70
Settled water ozone dose
1.3 mg/L
Settled water total organic carbon concentration
1.90 mg/L
Empty bed contact time in
biological activated carbon filters
9.4 minutes for granular activated
carbon layer
2.3 minutes for sand layer
Medium pressure UV dose.
25 mJ/cm2
Free chlorine dose
1.26 mg/L as C12
Free chlorine contact time
17.2 hours
Table S3. Water quality characteristics of surface water used in adsorption tests
Table S4. LC gradient method for PFAS analysis
Mobile phase A: 2 inM ammonium acetate in ultrapure water with 5% methanol
Mobile phase B: 2 mM ammonium acetate in acetoniitrile with 5% ultrapure water
Page 4 of 12
DEQ-CFW 00003339
Table S5. MS transitions for PFAS Analysis
Legacy PFASs
CompoundMS/MS
PFBA
212.8 - 168.8
Internal
13C4-PFBA
PFPeA
262.9 - 218.8
13C2- PFHxA
PFHxA
313.6 - 268.8
13C2- PFHxA
PFHpA
362.9 - 318.8
13C4- PFOA
PFOA
413.0 368.8
13C4- PFOA
PFNA
463.0 418.8
13C4- PFOA
PFDA
513.1--> 68.8
13C2-PFDA
PFBS
299.1- 98.8
1802-PFHxS
PFHxS
399.1 � 98.8
1802-PFHxS
PFOS
498.9 - 98.8
13C4-PFOS
PFECAs
PFMOAA
180.0 - 85.0
N/A
PFMOPrA
229.1 - 184.9
N/A
PFMOBA
279.0 - 234.8
N/A
PFPrOPrA
329.0 - 284.7
13C2- PFHxA
PF02HxA
245.1- 85.0
N/A
PF030A
311. - 84.9
N/A
PF04DA
377.1 --+ 85.0
N/A
Internal standards
Perfluoro-n-[1,2,3,4-13C4]butanoic acid
(13C4-PFBA)
217.0 - 172
Not applicable
pp
Perfluoro-n-[1,2-13C2]hexanoic acid
(13C2-PFHxA)
315.1 - 269.8
Perfluoro-n-[1,2,3,4-13C2]octanoic acid
(13C4-PFOA)
417.0 -> 372.0
Perfluoro-n-[1,2-13C2]decanoic acid
(13C2-PFDA)
515.1 -> 469.8
Sodium perfluoro-l-
hexane[1802]sulfonate (1802-PFHxS)
403.1-> 83.8
Sodium perfluoro-l-[1,2,3,4-13C4]octane
sulfonate (13C4-PFOS)
502.9 - 79.9
Page 5 of 12
DEQ-CFW 00003340
Table S6. Maximum,
minimum,
mean and median concentrations
Community
(ng/L) of PFASs at three drinking
water intakes.
PFBA
max
99
nun
<10
median•
26
33
38
<10
. ian
12
mean
12
:.max:
104
-nun median
<10
12
mean
22
PFPeA
191
14
44
62
38
<10
19
19
116
<10
30
36
PFHxA
318
<10
48
78
42
<10
<10
11
24
<10
<10
<10
PFHpA
324
<10
39
67
85
<10
<10
11
24
<10
<10
<10
PFOA
137
<10
34
46
32
<10
<10
<10
17
<10
<10
<10
PFNA
38
<10
<10
<10
<10
<10
<10
<10
<10
<10
<10
<10
PFDA
35
<25
<25
<25
<25
<25
<25
<25
<25
<25
<25
<25
PFB S
80
<10
<10
<10
11
<10
<10
<10
<10
<10
<10
<10
PFHxS
193
<10
10
14
14
<10
<10
<10
14
<10
<10
<10
PFOS
346
<25
29
44
43
<25
<25
<25
40
<25
<25
<25
PFPrOPrA
<10
<10
<10
<10
10
<10
<10
<10
4560
55
304
631
PFOA+PFOS
447
0
64
90
59
0
0
9
55
<10
<10
<10
E PFASs**
1502
18
212
355
189
0
47
62
4696
55
345
710
* Concentrations less than quantitation limits were considered as zero to calculate means and E PFASs.
** Other PFECAs were present in water samples from community C but could not be quantified and were therefore not included in
PFASs
Page 6of12
DEQ-CFW 00003341
F O
0---<
F�F OH
F F
PFMOAA
F F F O
O
F�
F F F OH
F
F
PFMOAA
PF02HxA
F F p
FO
�
F F OH
F
F
PFMOPrA
PFPrOPrA
F
//\ F
(F
O O
/ F
F p
F
F
O
F OH
PF030A
F F F FV
F
F O/�OY\p/ OH
F F F F F
PF04DA O
Figure S1. Molecular structures of PFECAs evaluated in this study
Page 7 of 12
DEQ-CFW 00003342
Cape Fear River watershed
H Haw a
River
Con f
N
L DWTP
DWT Rive
Deep River
Flow direction
Community B DW-IT
North Carolina Cape Fear River
jy Surface water sampling site
JIFA-.c) for FAC test
Cape /Fear river basin manufactLirinc,
L
plant
W Conu-nunity C
MT MN
MI ME
ID SO VA 1, DJAJJT.�
OR WY MI NY �!�H
NE [A
Surfacewat for
L NV IL ON wl—!�,NYCT' ID
UT V - -Mw6-
Co KS M 1" ,
KY VA
CA OK TN NC
NM
AR S M AL GA j
L
TX :r
100 km
Figure S2. Sampling sites in the Cape Fear River watershed, North Carolina. The scale is for the
Cape Fear River watershed map.
Page 8 of 12
DEQ-CFW-00003343
1200
:J 800
c
c
0 600
ca
c
CD
ci 400
c
0
U
200
0
Q�e`OQtP QF6 QFQe QF� pPQFOP QF�P PFOP PF� QF�,�`' QF QF oPxQFO`'
QF
200
150
J
C
0 100
c
a�
0
c
0 50
U
0
Q�Q`OQcPPFg QFQe QF� Q��pPPF�PPF�PP, O& 0 Q��'�`'PF�Q�oPxQF�c
Q
Page 9 of 12
DEQ-CFW 00003344
5000
4000
J
3000
c
0
ca
2000
aD
U
C
O
U
1000
0
• Community C •
•
-AL -•- -•- — — — -•-
PFP� jo"F0 QFPe ' '�eF��PeFOPPF�PPFOPPFP' QF��-b -B OPxPF�G
PF
Figure S3. PFAS concentration distributions in the CFR watershed at three drinking water
intakes. Concentrations less than quantitation limits were considered as zero. Upper and lower
edges of a box represent the 75th and 25thpercentile, respectively; the middle line represents the
median; upper and lower bars represent the 90thand 10th percentile, respectively; and dots
represent outliers (>90th or <10th percentile).
Page 10 of 12
DEQ-CFW 00003345
2.5E+07
2.0E+07
m
f 1.5E+07
3
0
1.0E+07
ti
R.
5.0E+06
0 0E+00
Community A
e Mean flow
a PFASs
.. 9
a
_ � a
a � a
a
a �
a d" 6
a�
2500
2000
409
0
6/15/13 7/30/13 9/13/13 10/28/13 12/12/13
5. E+07
4. E+07
a
3. E+07
3
0
4-
2. E+07
v
0
1. E+07
0. E+00
5 00
400
300
200 LL
a
w
100
0
6/15/13 7/30/13 9/13/13 10/28/13 12/12/13
6.E+0/
5. E+07
4. E+07
o 3.E+07
c
2.E+07
1. E+07
0 E+00
6/1/13 7/1/13 7/31/13 8/30/13 9/29/13
5000
4000 -
ap
3000
2000 w
1000
0
Figure S4. Total PFAS concentrations in the source water and stream flow at the three studied
DWTPs. Stream flow data were acquired from US Geological Survey stream gage records
Page 11 of 12
DEQ-CFW 00003346
lUU7o
a
B0•D
60%
0 40%
a
203/.
0%
-20%
0 20 40 60 80 100 120 140
time (min)
-P-PFBA tPFPeA -PFHxA--X-PFHpA -.-PFOA
-P-PFNA-o-PFDA-o--PFBS PFHxS -*-PFOS
100%
BOIA
60.A ^y:
'0 4CM
E _
m
20%
0%
-20%
0 20 40 60 80 100 120 140
time (min)
---PFBA--m--PFPeA -& PFHxA--X-PFHpA ='�PFOA
-n-PFNA-O-PFDA -o-PFBS -PFHS - -PFOS
100%
Bo•� e� -.:-- -- —
0 60%
0 40D%
E
m
20•�
0%
-20%
0 20 40 60 80 100 120 140
time (min)
--O--PFBA-4-PFPeA--:--PFHxA --XEPFHpA -I: P,FOA
-�PFNA -C�-PFDA-o--PFBS PFHxS---PFOS
lUU7o
80% b .
60%
m -
E 40%
e 20% - -
0%
-20%
0 20 40 60 80 100 120 140
time (min)
-4-PFMOPrA-M-PFMOBA PFPrOPrA
-0-PF02HxA-0-PF030A PF04DA
1UU7U
d _
80•�
60%
0 40%
w
20% -
-20%
0 20 40 60 80 100 120 140
time (min)
-4-PFMOPrA-M-PFMOBA - PFPrOPrA
-4-PF02HxA-0-PF030A = PF04DA
IUU7a . . ..... .. ... ... ..
80•� f
60%
m
o 40%
E
a
20•/
0%
-20%
0 20 40 60 80 100 120 140
time (min)
-4-PFMOPrA -0-PFMOBA PFPrOPrA
-0-PF02HxA-0-PF030A PF04DA
Figure S5. PFAS adsorption at powdered activated carbon doses of (a, b) 30 mg/L, (c, d) 60 mg/L
and (e, f)100 mg/L. Figures show average PFAS removal percentages of duplicate tests.
Reference
1. Nakayama, S.; Strynar, M. J.; Helfant, L.; Egeghy, P.; Ye, X.; Lindstrom, A. B.,
Perfluorinated compounds in the Cape Fear drainage basin in North Carolina. Environ. Sci.
Technol. 2007, 41, (15), 5271-5276.
Page 12 of 12
DEQ-CFW 00003347