HomeMy WebLinkAbout2021.07.30_CCO.p11a_pfas non targeted analysis and methods interim report 3 20210730
The Chemours Company
Fayetteville Works
22828 NC Highway 87 W
Fayetteville, NC 28306
PFAS NON-TARGETED ANALYSIS AND
METHODS INTERIM REPORT #3
Process and Non-Process Wastewater and Stormwater
Prepared by
The Chemours Company FC, LLC
Fayetteville Works
22828 NC Highway 87 W
Fayetteville, NC 28306
July 30, 2021
The Chemours Company
Fayetteville Works
22828 NC Highway 87 W
Fayetteville, NC 28306
ii 30 July 2021
TABLE OF CONTENTS
1 INTRODUCTION ...............................................................................................................4
2 EXPERIMENTAL METHODS...........................................................................................5
2.1 Investigation of the Four Related Unknown PFAS in General Facility Discharge
Samples .......................................................................................................................5
2.2 Investigation of the Fifth Unknown PFAS in General Facility Discharge Samples...6
2.3 Investigation of the Five Most Abundant Unknown PFAS in Chemours Process
Wastewater Samples ...................................................................................................6
3 RESULTS AND DISCUSSION ..........................................................................................6
3.1 Investigation of the 4 Related Unknown PFAS in General Facility Discharge
Samples .......................................................................................................................6
3.2 Investigation of the Fifth Unknown PFAS in General Facility Discharge Samples...8
3.3 Explanation of the Initial Identification of Acetate Clusters as PFAS Unknowns .....8
3.4 Chemours Process Wastewater Samples ....................................................................9
4 SUMMARY AND NEXT STEPS .......................................................................................9
5 REFERENCES ..................................................................................................................10
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LIST OF TABLES
Table 1: Status of 10 Unknown PFAS - Interim Report #3
LIST OF FIGURES
Figure 1: Extracted Ion Chromatograms of Demineralized Water and Demineralized Water
Through Which Trifluoroethylene Has Been Purged
Figure 2: Mass Spectra of Four Unknowns in a General Facility Discharge Sample
Analyzed with Acetate and with Formate as the LC Eluent
Figure 3: Mass Spectra of Four Unknowns in a General Facility Discharge Sample
Analyzed with Deuterated Acetate as the LC Eluent
Figure 4: Mass Spectrum of a General Facility of the Fifth Unknown in a General Facility
Discharge Sample Analyzed with Deuterated Acetate as the LC Eluent
Figure 5: Mass Spectra of Chemours Process Wastewater Unknown C8HF13O4 and of EVE
Acid
ACRONYMS AND ABBREVIATIONS
CFRW Cape Fear River Watch
Chemours The Chemours Company FC, LLC
Da dalton
EIC extracted ion chromatogram
Facility Chemours Fayetteville Works, North Carolina
LC liquid chromatography
MS mass spectrometry
MS-MS tandem mass spectrometry
m/z mass-to-charge ratio
NCDEQ NC Department of Environmental Quality
PFAS per- and polyfluoroalkyl substances
QToF quadrupole time-of-flight
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1 INTRODUCTION
This interim report has been prepared by The Chemours Company FC, LLC (Chemours) to provide
an update on the characterization of previously unidentified per- and polyfluoroalkyl substances
(PFAS) in aqueous samples collected from process wastewater, non-process wastewater (i.e., non-
contact cooling water) and stormwater at the Chemours Fayetteville Works, North Carolina site
(the Facility). This work is being conducted pursuant to Paragraph 11 subpart (a) in the Consent
Order executed 25 February 2019 between Chemours and the North Carolina Department of
Environmental Quality (NCDEQ) with the Cape Fear River Watch (CFRW) as intervenor. The
overall purpose of this program is to identify previously unknown PFAS that may be present in
samples of collected water and to develop standards and methods to facilitate the quantitative
analysis of these PFAS, as described in the PFAS Non-Targeted Analysis and Methods
Development Plan, Version 2 (Chemours and Geosyntec, 2019). This is the third interim report.
In the first interim report (Chemours, 2020a), the five most abundant unknown PFAS in General
Facility Discharge samples (samples of stormwater, treated non-Chemours process wastewater
and/or non-contact cooling water discharging to the Cape Fear River) and in Chemours Process
Wastewater samples (samples of process wastewater from Chemours manufacturing areas) were
identified using liquid chromatography (LC) coupled to high-resolution quadrupole time-of-flight
(QToF) mass spectrometry. The five most abundant unknown PFAS in the General Facility
Discharge samples were identified as C4H5F3O2, C4H2F4O2, C6H6F6O2, C8H7F9O2 and C10H8F12O2.
The five most abundant unknown PFAS in the Chemours Process Wastewater samples were
identified as C8H2F14O7S, C8HF13O4, C8H5F13O6S, C9H2F14O6 and C6HF11O4. None of the
identified five potential PFAS compounds in the General Facility Discharge samples were
represented in the five potential PFAS compounds in the Chemours Process Wastewater samples.
These ten (10) unknown PFAS were advanced to the next step in the program - identifying
molecular structures.
In the second interim report (Chemours, 2020b), investigation into the five most abundant
unknown PFAS in the General Facility Discharge samples revealed that four of the compounds
(C4H5F3O2, C6H6F6O2, C8H7F9O2 and C10H8F12O2) coeluted from the LC. These compounds have
different molecular weights and were therefore expected to be chromatographically resolved.
Examination of the empirical formulas showed that the four compounds are related by C2HF3, that
is, the addition of C2HF3 (trifluoroethylene, which is a potential impurity in tetrafluoroethylene, a
feedstock at the Facility) to each compound generates the empirical formula of the following
compound. This suggested that these four compounds may represent a single compound,
C4H5F3O2, which, upon elution from the LC, undergoes adduction1 of C2HF3 in the ion source of
1 Adduction is the process of the direct addition of two or more distinct molecules that result in a single reaction
product referred to as an adduct which containing all atoms of the two initial reaction molecules.
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the mass spectrometer. Furthermore, the single compound C4H5F3O2 itself could be generated from
a reaction between C2HF3 and acetate (CH3COO-, present in the LC eluent) in the ion source of
the mass spectrometer. The fifth unknown PFAS, C4H2F4O2, was not present in the samples at
high enough concentrations to analyze by the QToF mass spectrometer.
In the second interim report (Chemours, 2020b), investigation into the five most abundant
unknown PFAS in the Chemours Process Wastewater samples concluded:
C8H2F14O7S: the structure was determined to be CF3-CF(COOH)-O-CF2-CF(CF3)-O-
CF2-CF2-SO3H
C8HF13O4: a structure was tentatively identified for this unknown PFAS, however,
background interference in the samples had to date interfered with confirmation of the
tentatively identified structure
C8H5F13O6S: the structure was determined to be HO3S-CF2-CF2-O-CF(CF3)-CF2-O-CHF-
CF2-OCH3
C9H2F14O6: the structure was tentatively determined to be HOOC-CF2-CF2-O-CF(CF3)-
CF2-O-CF(CF3)-COOH
C6HF11O4 - a structure was not yet identified; background contamination in the samples
had to date interfered with confirmation of a tentatively identified structure.
This third interim report provides an update on efforts completed to further identify the structures
of the five most abundant unknown PFAS in the General Facility Discharge samples and the five
most abundant unknown PFAS in the Chemours Process Wastewater samples.
The remainder of this report consists of:
Section 2: Experimental Methods;
Section 3: Results and Discussion; and
Section 4: Summary and Next Steps.
2 EXPERIMENTAL METHODS
2.1 Investigation of the Four Related Unknown PFAS in General Facility Discharge
Samples
To investigate the possibility that trifluoroethylene (an impurity in tetrafluoroethylene) combines
with acetate (present in the LC eluent) in the ion source of the mass spectrometer to produce
C4H5F3O2, with possible subsequent additions of trifluoroethylene to produce C6H6F6O2,
C8H7F9O2 and C10H8F12O2, three experiments were conducted:
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1) Trifluoroethylene was purged into demineralized water to create an aqueous solution of
trifluoroethylene. This solution was then analyzed by LC-QToF using acetate buffer to
look for the presence of the 141, 223, 305, 387 mass-to-charge ratio (m/z) ions
corresponding to the m/z of C4H5F3O2, C6H6F6O2, C8H7F9O2 and C10H8F12O2.
2) A General Facility Discharge sample (from Location 20 [Outfall 002 to Cape Fear River])
was analyzed by LC-QToF using formate (HCOO-) buffer instead of acetate (CH3COO-)
buffer. Formate has a molecular weight of 45 daltons (Da) versus acetate which has a
molecular weight of 59 Da.
3) A General Facility Discharge sample (from Location 20) was analyzed by LC-QToF using
deuterated (isotopically labelled) acetate buffer (CD3COO-) as well as native acetate
(CH3COO-) buffer to assess observed mass shifts. Deuterated acetate has a molecular
weight of 62 Da versus native acetate which has a molecular weight of 59 Da.
2.2 Investigation of the Fifth Unknown PFAS in General Facility Discharge Samples
The fifth unknown PFAS in the General Facility Discharge samples was analyzed with deuterated
acetate buffer as well as native (unlabelled) acetate buffer by LC-QToF to assess any observed
mass shifts.
2.3 Investigation of the Five Most Abundant Unknown PFAS in Chemours Process
Wastewater Samples
Three of the five most abundant unknown PFAS in the Chemours Process Wastewater samples
were further investigated by extensively cleaning the analytical instrument to minimize
background contamination and by comparison of the QToF fragmentation mass spectra to those
of known compounds.
3 RESULTS AND DISCUSSION
3.1 Investigation of the 4 Related Unknown PFAS in General Facility Discharge Samples
An extracted ion chromatogram (EIC) was produced for the demineralized water through which
trifluoroethylene had been purged, as well as for the demineralized water alone. The ions extracted
were the 141, 223, 305, 387 m/z ions corresponding to the m/z of C4H5F3O2, C6H6F6O2, C8H7F9O2
and C10H8F12O2 (Figure 1). The results show that the EICs of the demineralized water alone and
the demineralized water with trifluoroethylene purged through it are indistinguishable, which
indicates that C4H5F3O2, C6H6F6O2, C8H7F9O2 and C10H8F12O2 are not present in either sample.
This may mean that trifluoroethylene is not combining with acetate in the MS to produce
C4H5F3O2, with possible subsequent additions of trifluoroethylene to produce C6H6F6O2,
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C8H7F9O2 and C10H8F12O2; however, it may also mean that there was insufficient trifluoroethylene
in the demineralized water following the purging step for the reactions, if possible, to occur.
A test was then conducted in which a General Facility Discharge sample, previously analyzed with
acetate buffer as the LC eluent and showing the presence of the 141, 223, 305, 387 m/z ions, was
analyzed with formate buffer as the LC eluent. This tested the theory that acetate (molecular weight
59 Da) reacts with trifluoroethylene (molecular weight 82 Da) to produce the 141 m/z ion, with
subsequent sequential additions of trifluoroethylene to produce the 223, 305 and 387 m/z ions. The
same reactions with formate should produce 127, 209, 291 and 373 m/z ions (that is, ions that are
14 Da lighter, because formate is 14 Da lighter than acetate). Mass spectral results, however,
showed that the 127, 209, 291 and 373 m/z ions were not present (Figure 2). Instead, ions
representing the adduction of formate (molecular weight 45 Da) with a repeating unit of 68 Da
(113, 181, 249 and 317 m/z) were observed. The composition of the 68 Da repeating unit was not
clear from this experiment. However, the results showed that the 141 m/z unknown was not
composed of trifluoroethylene plus acetate, nor were the subsequent unknowns (223, 305, 387
m/z) formed by the addition of repeating units of trifluoroethylene (molecular weight 82 Da). The
composition of the buffer (formate versus acetate) is integral to the composition of the 4 related
unknowns, and trifluoroethylene is not.
A subsequent test was conducted in which the General Facility Discharge sample was analyzed
with isotopically labelled acetate buffer. Mass spectral results showed that the 141, 223, 305, 387
m/z ions produced with the native acetate buffer shifted to 147, 232, 317 and 402 m/z, representing
mass increases of 6, 9, 12 and 15 Da, respectively (Figure 3). Because the isotopically labelled
acetate is 3 Da heavier than the native acetate, this showed that the initial 141 m/z unknown (which
increased by 6 Da) contained 2 acetate moieties, the 223 m/z unknown (which increased by 9 Da)
contained 3 acetate moieties, the 305 m/z unknown (which increased by 12 Da) contained 4 acetate
moieties, and the 387 m/z unknown (which increased by 15 Da) contained 5 acetate moieties.
The composition of the 82 Da moiety that is the difference between the 141, 223, 305 and 387 m/z
ions, as well as between acetate and the 141 m/z ion, has been shown to not be trifluoroethylene
(molecular weight 82 Da). Additionally, it has been shown that the 141 m/z ion contains two
acetate moieties (molecular weight 59 Da each, for a total of 118 Da). If 118 Da are subtracted
from 141, the remaining mass is 23 Da, which is the atomic weight of a sodium ion; sodium ions
are present in the water sample. The 82 Da moiety is, therefore, considered to be composed of
sodium acetate.
The first four unknowns, corresponding to 141, 223, 305, 387 m/z ions, can now be explained as
acetate clusters, and are not PFAS. An acetate molecule (molecular weight 59 Da) combined with
sequential sodium acetate molecules (molecular weight 82 Da) produces the observed 141, 223,
305 and 387 m/z ions. When native acetate is replaced with deuterated acetate (molecular weight
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62 Da) in the LC eluent, it combines with sequential deuterated sodium acetate molecules
(molecular weight 85 Da) to produce the observed 147, 232, 317 and 402 m/z ions. When acetate
is replaced with formate in the LC eluent, a formate molecule (molecular weight 45 Da) combined
with sequential sodium formate molecules (molecular weight 68 Da) produces the observed 113,
181, 249 and 317 m/z ions. When the analysis is conducted with demineralized water through
which trifluoroethylene had been purged (and native acetate buffer as the LC eluent), none of the
141, 223, 305, 387 m/z ions are observed because there is no sodium present (the sodium originates
from the groundwater matrix of the sample, and there is no groundwater present in this
experiment).
3.2 Investigation of the Fifth Unknown PFAS in General Facility Discharge Samples
The fifth unknown, with a m/z ratio of 157 and proposed in the second interim report to have an
empirical formula of C4H2F4O2, was present in General Facility Discharge samples at
concentrations too low with respect to background compounds to be able to propose a structure.
In the second interim report, cleanup of the sample and concentration of the unknown was
proposed. Given the results of the analysis of the other four unknown PFAS, however, the
unknown was first analyzed with isotopically labelled acetate. Mass spectral results showed a shift
of the 157 m/z peak by 6 Da to 163 Da, indicating that the 157 m/z peak contains two acetate
moieties (Figure 4). If two acetate moieties (molecular weight 59 Da each, for a total of 118 Da)
are subtracted from 157, the remaining mass is 39 Da, which is the atomic weight of a potassium
ion, which are present in the water sample. The fifth unknown can now be explained as a
potassium acetate cluster and is not a PFAS.
3.3 Explanation of the Initial Identification of Acetate Clusters as PFAS Unknowns
In this non-targeted analysis program, unknown PFAS were identified from unidentified
chromatographic peaks from a QToF mass spectrometer with a signal-to-noise level greater than
six and using the atomic mass defect of fluorine as the molecular feature. An atomic mass defect
refers to the phenomenon that the mass of an atom is not exactly equal to the number of subatomic
particles (protons and neutrons) or the atomic mass number (except for carbon-12 by definition)
as a result of differences in mass lost (as energy) when the atomic nucleus is formed for each
isotope. In this case, fluorine is well-known to have a negative mass defect, where the exact mass
is slightly less than the mass number. When the QToF mass spectrometer is operated in the
negative mode, one can select fluorine-containing features and empirical formulas using available
software provided by the instrument vendor. (The exact procedures utilized adhered closely to
what was outlined in McCord & Strynar (2019) which consists of using a software workflow of
Agilent ProFinder, MassHunter, and Mass Profile.) However, the algorithm used to determine
empirical formulas using the fluorine mass defect is not exact, especially when an unknown
number of fluorines is present in the unknown compound; this is a known limitation of the mass
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defect approach. Consequently, the algorithm may occasionally determine that an unknown
compound contains fluorine when it does not, as is the case for the five most abundant unknown
“PFAS” in the General Facility Discharge samples. In this case, both oxygen and sodium have
negative mass defects and the five unknowns, four containing both oxygen and sodium and one
containing oxygen, were mistakenly flagged as fluorinated.
3.4 Chemours Process Wastewater Samples
Progress in investigating the five most abundant potential PFAS compounds in the Chemours
Process Wastewater samples is summarized below:
C8HF13O4 - a structure was tentatively identified for this unknown PFAS in interim report
#2, however, background contamination interfered with confirmation of the tentatively
identified structure. Following cleanup of the analytical instrument, a cleaner mass
spectrum was obtained and confirmed to correspond to EVE Acid (Figure 5). EVE Acid
(Chemical Abstracts Service Number 69087-46-3) has previously been identified as a
Site-related PFAS and is found on the Table 3+ analyte list.
C8H5F13O6S - a tentative structure (HO3S-CF2-CF2-O-CF(CF3)-CF2-O-CHF-CF2-OCH3)
was identified for this unknown PFAS in interim report #2. An authentic standard was
found to exist for this compound; however, the unknown PFAS did not match the
retention time nor the MS-MS mass spectrum of the authentic standard. Consequently,
the tentatively identified structure will be revised, followed by initiation of an authentic
standard to confirm the structure.
C6HF11O4 - a tentative structure could not be identified for this unknown PFAS in interim
report #2 due to background contamination. Following cleanup of the analytical
instrument, a tentative structure (CF3-O-CF2-O-CF2-CF2-CF2-COOH) was identified.
Synthesis of an authentic standard to confirm this structure has been initiated.
These results are summarized in Table 1.
4 SUMMARY AND NEXT STEPS
A summary of the next steps for each of the 10 potential PFAS compounds discussed in this interim
report is provided below and in Table 1.
The five most abundant unknown “PFAS” in the General Facility Discharge samples have been
shown to be sodium or potassium adducts of acetate clusters, containing no fluorine, rather than
PFAS. They can therefore be eliminated from the list of unknown PFAS. The next most abundant
potential PFAS in the General Facility Discharge samples (C8HF15O8) had an ion abundance of
3.3x107 (Chemours, 2020a). This is two orders of magnitude smaller than the ion abundance of
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the unknown PFAS in the Chemours Process Wastewater samples (the five most abundant
unknown PFAS in the Chemours Process Wastewater samples had an ion abundance ranging from
3.8x109 to 4.5x109). Chemours will commence investigating the next five unknown PFAS in the
General Facility Discharge samples; however, their low concentration reduces the possibility of
identifying potential structures. Upcoming efforts for the non-targeted analysis program will be
focused on the unknown PFAS in the Chemours Process Wastewater samples.
The identification of three of the five most abundant unknown PFAS in the Chemours Process
Wastewater samples was advanced. One compound (C8HF13O4) was identified as EVE Acid and
is therefore no longer unknown. One compound’s (C8H5F13O6S) tentatively identified structure
was found to not match an existing authentic standard, and a new structure will be tentatively
identified. One compound (C6HF11O4) was tentatively identified as CF3-O-CF2-O-CF2-CF2-CF2-
COOH. Authentic standard synthesis has been initiated for this compound, as well as for the other
two compounds (C8H2F14O7S and C9H2F14O6), for which structures had been previously
tentatively identified.
5 REFERENCES
Chemours, 2020a. PFAS Non-Targeted Analysis and Methods Interim Report. June 30, 2020.
Chemours, 2020b. PFAS Non-Targeted Analysis and Methods Interim Report #2. December 31,
2020.
Chemours and Geosyntec Consultants, 2019. PFAS Non-Targeted Analysis and Methods
Development Plan. Version 2. December 5, 2019.
McCord, J. and Strynar, M., 2019. Identification of per-and polyfluoroalkyl substances in the
Cape Fear river by high resolution mass spectrometry and nontargeted screening.
Environmental science & technology, 53(9), pp. 4717-4727.
TABLE 1STATUS OF 10 UNKNOWN PFAS - INTERIM REPORT #3Chemours Fayetteville Works, North CarolinaSample SourceSuggested Empirical FormulaMass(Da)Mass toCharge Ratio(m/z)Identified Structure Next StepsC4H5F3O2142.0241 141.0168C4H2F4O2157.9983 156.9910C6H6F6O2224.0272 223.0199C8H7F9O2306.0302 305.0230C10H8F12O2388.0331 387.0258C8H2F14O7S507.9302 506.9229Structure tentatively identified:CF3-CF(COOH)-O-CF2-CF(CF3)-O-CF2-CF2-SO3HContinue synthesis of authentic standardC8HF13O4407.9670 406.9598Identified as EVE Acid (background interferences prevented identification previously)NoneC8H5F13O6S475.9587 474.9515Tentatively identified structure did not match authentic standard.Revise tentatively identified structure and initiate synthesis of authentic standardC9H2F14O6471.9630 470.9556Structure tentatively identified:HOOC-CF2-CF2-O-CF(CF3)-CF2-O-CF(CF3)-COOHContinue synthesis of authentic standardC6HF11O4345.9693 344.9620Structure tentatively identified:CF3-O-CF2-O-CF2-CF2-CF2-COOHContinue synthesis of authentic standardNotes:adduct - a product of a direct addition of two or more distinct molecules resulting in a single reaction product containing all atoms of all componentsC - carbonDa - daltonF - fluorineH - hydrogenLC - liquid chromatographMS - mass spectrometerO - oxygenPFAS - per- and polyfluoroalkyl substancesS - sulfurChemours Process WastewaterChemours will commence investigating the next five unknown PFAS in the General Facility Discharge samples; however, their low concentration reduces the possibility of identifying potential structures. General Facility DischargeStructures identified as sodium or potassium adducts of acetate clusters; these are formed in the MS source from sodium or potassium present in the sample matrix and acetate from the LC eluent buffer July 2021
Notes:- the mass-to-charge ratios of four ions (141, 223, 305 and 387 mass-to-charge ratio), representing the four related unknowns in the General Facility Discharge samples, are combined in the extracted ion chromatogramsFigure1July 2021Extracted Ion Chromatograms of Demineralized Water and Demineralized Water Through Which Trifluoroethylene Has Been PurgedChemours Fayetteville Works, North CarolinaDemineralized waterDemineralized water through which trifluoroethylene has been purged
Notes:Mass Spectra of Four Unknowns in a General Facility Discharge Sample Analyzed with Acetate and with Formate as the LC EluentChemours Fayetteville Works, North CarolinaFigure2July 2021Da - daltonLC - liquid chromatographacetate+ 82 Da+ 82 Da+ 82 Da+ 82 Da+ 68 Da+ 68 Da+ 68 Da+ 68 DaformateLC eluent: ammonium acetate LC eluent: ammonium formate - four unknown peaks (141, 223, 305 and 387 m/z) initaially proposed to be acetate plus addition of repeating units of trifluoroethylene (molecular weight 82 Da)- expected ions composed of formate+trifluoroethylene (127, 209, 291 and 373 m/z) are not seen- instead, ions composed of formate plus a repeating unit of 68 Da are seen
Notes:CH3COO- - native acetateCD3COO- - deuterated acetateDa - daltonNa+ - sodium ionLC - liquid chromatographMass Spectra of Four Unknowns in a General Facility Discharge Sample Analyzed with Deuterated Acetate as the LC EluentChemours Fayetteville Works, North CarolinaFigure3July 2021CD3COO-(CD3COO-)2+Na+(CD3COO-)3+2Na+(CD3COO-)4+3Na+(CD3COO-)5+4Na+CH3COO-(CH3COO-)2+Na+(CH3COO-)3+2Na+(CH3COO-)4+3Na+(CH3COO-)5+4Na+LC eluent: ammonium acetate LC eluent: deuterated ammonium acetate
Notes:CH3COO- - native acetateCD3COO- - deuterated acetateDa - daltonK+ - potassium ionLC - liquid chromatographMass Spectra of the Fifth Unknown in a General Facility Discharge Sample Analyzed with Deuterated Acetate as the LC EluentChemours Fayetteville Works, North CarolinaFigure4July 2021(CH3COO-)2+K+(CD3COO-)2+K+LC eluent: ammonium acetate LC eluent: deuterated ammonium acetate
Notes:MS/MS - tandem mass spectrometryrt - retention timeMass Spectra of Eve Acid and of Chemours Process Wastewater Unknown C8HF13O4 Chemours Fayetteville Works, North CarolinaFigure5July 2021MS/MS fragmentation of EVE Acid standardMS/MS fragmentation of Chemours Process Wastewater Unknown C8HF13O4