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      An overview of the uses of per- and polyfluoroalkyl substances (PFAS)

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          Abstract

          Systematic description of more than 200 uses of PFAS and the individual substances associated with each of them (over 1400 PFAS in total).

          Abstract

          Per- and polyfluoroalkyl substances (PFAS) are of concern because of their high persistence (or that of their degradation products) and their impacts on human and environmental health that are known or can be deduced from some well-studied PFAS. Currently, many different PFAS (on the order of several thousands) are used in a wide range of applications, and there is no comprehensive source of information on the many individual substances and their functions in different applications. Here we provide a broad overview of many use categories where PFAS have been employed and for which function; we also specify which PFAS have been used and discuss the magnitude of the uses. Despite being non-exhaustive, our study clearly demonstrates that PFAS are used in almost all industry branches and many consumer products. In total, more than 200 use categories and subcategories are identified for more than 1400 individual PFAS. In addition to well-known categories such as textile impregnation, fire-fighting foam, and electroplating, the identified use categories also include many categories not described in the scientific literature, including PFAS in ammunition, climbing ropes, guitar strings, artificial turf, and soil remediation. We further discuss several use categories that may be prioritised for finding PFAS-free alternatives. Besides the detailed description of use categories, the present study also provides a list of the identified PFAS per use category, including their exact masses for future analytical studies aiming to identify additional PFAS.

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          Perfluoroalkyl and Polyfluoroalkyl Substances in the Environment: Terminology, Classification, and Origins

          Robert Buck, James Franklin, Urs Berger (2011)
          The primary aim of this article is to provide an overview of perfluoroalkyl and polyfluoroalkyl substances (PFASs) detected in the environment, wildlife, and humans, and recommend clear, specific, and descriptive terminology, names, and acronyms for PFASs. The overarching objective is to unify and harmonize communication on PFASs by offering terminology for use by the global scientific, regulatory, and industrial communities. A particular emphasis is placed on long-chain perfluoroalkyl acids, substances related to the long-chain perfluoroalkyl acids, and substances intended as alternatives to the use of the long-chain perfluoroalkyl acids or their precursors. First, we define PFASs, classify them into various families, and recommend a pragmatic set of common names and acronyms for both the families and their individual members. Terminology related to fluorinated polymers is an important aspect of our classification. Second, we provide a brief description of the 2 main production processes, electrochemical fluorination and telomerization, used for introducing perfluoroalkyl moieties into organic compounds, and we specify the types of byproducts (isomers and homologues) likely to arise in these processes. Third, we show how the principal families of PFASs are interrelated as industrial, environmental, or metabolic precursors or transformation products of one another. We pay particular attention to those PFASs that have the potential to be converted, by abiotic or biotic environmental processes or by human metabolism, into long-chain perfluoroalkyl carboxylic or sulfonic acids, which are currently the focus of regulatory action. The Supplemental Data lists 42 families and subfamilies of PFASs and 268 selected individual compounds, providing recommended names and acronyms, and structural formulas, as well as Chemical Abstracts Service registry numbers. Integr Environ Assess Manag 2011;7:513–541. © 2011 SETAC
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            Sources, fate and transport of perfluorocarboxylates.

            Konstantinos Prevedouros, Ian T Cousins, Robert Buck (2006)
            This review describes the sources, fate, and transport of perfluorocarboxylates (PFCAs) in the environment, with a specific focus on perfluorooctanoate (PFO). The global historical industry-wide emissions of total PFCAs from direct (manufacture, use, consumer products) and indirect (PFCA impurities and/or precursors) sources were estimated to be 3200-7300 tonnes. It was estimated that the majority (approximately 80%) of PFCAs have been released to the environment from fluoropolymer manufacture and use. Although indirect sources were estimated to be much less importantthan direct sources, there were larger uncertainties associated with the calculations for indirect sources. The physical-chemical properties of PFO (negligible vapor pressure, high solubility in water, and moderate sorption to solids) suggested that PFO would accumulate in surface waters. Estimated mass inventories of PFO in various environmental compartments confirmed that surface waters, especially oceans, contain the majority of PFO. The only environmental sinks for PFO were identified to be sediment burial and transport to the deep oceans, implying a long environmental residence time. Transport pathways for PFCAs in the environment were reviewed, and it was concluded that, in addition to atmospheric transport/degradation of precursors, atmospheric and ocean water transport of the PFCAs themselves could significantly contribute to their long-range transport. It was estimated that 2-12 tonnes/ year of PFO are transported to the Artic by oceanic transport, which is greater than the amount estimated to result from atmospheric transport/degradation of precursors.
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              Discovery of 40 Classes of Per- and Polyfluoroalkyl Substances in Historical Aqueous Film-Forming Foams (AFFFs) and AFFF-Impacted Groundwater.

              Krista Barzen-Hanson, Karl Oetjen, Sarah J Choyke (2017)
              Aqueous film-forming foams (AFFFs), containing per- and polyfluoroalkyl substances (PFASs), are released into the environment during response to fire-related emergencies. Repeated historical applications of AFFF at military sites were a result of fire-fighter training exercises and equipment testing. Recent data on AFFF-impacted groundwater indicates that ∼25% of the PFASs remain unidentified. In an attempt to close the mass balance, a systematic evaluation of 3M and fluorotelomer-based AFFFs, commercial products, and AFFF-impacted groundwaters from 15 U.S. military bases was conducted to identify the remaining PFASs. Liquid chromatography quadrupole time-of-flight mass spectrometry was used for compound discovery. Nontarget analysis utilized Kendrick mass defect plots and a "nontarget" R script. Suspect screening compared masses with those of previously reported PFASs. Forty classes of novel anionic, zwitterionic, and cationic PFASs were discovered, and an additional 17 previously reported classes were observed for the first time in AFFF and/or AFFF-impacted groundwater. All 57 classes received an acronym and IUPAC-like name derived from collective author knowledge. Thirty-four of the 40 newly identified PFAS classes derive from electrochemical fluorination (ECF) processes, most of which have the same base structure. Of the newly discovered PFASs found only in AFFF-impacted groundwater, 11 of the 13 classes are ECF-derived, and the remaining two classes are fluorotelomer-derived, which suggests that both ECF- and fluorotelomer-based PFASs are persistent in the environment.
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                Author and article information

                Contributors
                Juliane Glüge: (View ORCID Profile)
                Martin Scheringer: (View ORCID Profile)
                Ian T. Cousins: (View ORCID Profile)
                Dorte Herzke: (View ORCID Profile)
                Rainer Lohmann: (View ORCID Profile)
                Carla A. Ng: (View ORCID Profile)
                Journal
                Journal ID (publisher-id): ESPICZ
                Title: Environmental Science: Processes & Impacts
                Abbreviated Title: Environ. Sci.: Processes Impacts
                Publisher: Royal Society of Chemistry (RSC)
                ISSN (Print): 2050-7887
                ISSN (Electronic): 2050-7895
                Publication date Created: 2020
                Publication date (Electronic): 2020
                Affiliations
                [1 ]Institute of Biogeochemistry and Pollutant Dynamics
                [2 ]ETH Zürich
                [3 ]8092 Zürich
                [4 ]Switzerland
                [5 ]Department of Environmental Science
                [6 ]Stockholm University
                [7 ]SE-10691 Stockholm
                [8 ]Sweden
                [9 ]Department of Pharmacology & Toxicology
                [10 ]Brody School of Medicine
                [11 ]East Carolina University
                [12 ]Greenville
                [13 ]USA
                [14 ]Milieu
                [15 ]Brussels
                [16 ]Belgium
                [17 ]NILU
                [18 ]Norwegian Institute for Air Research
                [19 ]Tromsø
                [20 ]Norway
                [21 ]Department of Arctic and Marine Biology
                [22 ]Graduate School of Oceanography
                [23 ]University of Rhode Island
                [24 ]Narragansett
                [25 ]Departments of Civil and Environmental Engineering and Environmental and Occupational Health
                [26 ]University of Pittsburgh
                [27 ]Pittsburgh
                [28 ]European Environment Agency
                [29 ]DK-1050 Copenhagen K
                [30 ]Denmark
                [31 ]Chair of Ecological Systems Design
                [32 ]Institute of Environmental Engineering
                [33 ]8093 Zürich
                Article
                DOI: 10.1039/D0EM00291G
                PMC ID: 7784712
                PubMed ID: 33125022
                SO-VID: 4180ded6-f1cd-4d05-b589-5081009e8e2d
                Copyright © © 2020
                License:

                http://creativecommons.org/licenses/by-nc/3.0/

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