DOCSLIB.ORG

Toxicity Characteristic and F-Listed Solvents

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Toxicity Characteristic and F-Listed Solvents Common Chemical Name CAS # Common Chemical Name CAS # mercury (D009) 7439-97-6 phenyl methane (toluene) 108-88-3 methacide (toluene) 108-88-3 pimelic ketone (cyclohexanone) 108-94-1 methanol (F003) 67-56-1 pyridine (F005; D038) 110-86-1 methoxy ddt (methoxychlor) 72-43-5 santophene 20 (pentachlorophenol) 87-86-5 methoxychlor (D014) 72-43-5 selenium (D010) 7782-49-2 methyl benzene (toluene) 108-88-3 silver (D011) 7440-22-4 methyl ethyl ketone (F005; D035) 78-93-3 tce (trichloroethylene) 79-01-6 methyl isobutyl ketone (F005) 108-10-1 technical chlorinated camphene (toxaphene) 8001-35-2 methyl chloroform (1,1,1-trichloroethane) 71-55-6 tetracap (tetrachloroethylene) 127-18-4 methylene bichloride (methylene chloride) 75-09-2 tetrachloroethene (tetrachloroethylene) 127-18-4 methylene chloride (F001) 75-09-2 tetrachloroethylene (F001; D039) 127-18-4 methylene dichloride (methylene chloride) 75-09-2 tetrachloromethane (carbon tetrachloride) 56-23-5 methylphenol (cresol) 1319-77-3 tetropil (tetrachloroethylene) 127-18-4 monochlorobenzene (chlorobenzene) 108-90-7 toluene (F005) 108-88-3 nitrobenzol (nitrobenzene) 98-95-3 toluol (toluene) 108-88-3 o-cresol (D023) 95-48-7 toxaphene (D015) 8001-35-2 o-cresylic acid (o-cresol) 95-48-7 trethylene (trichloroethylene) 79-01-6 o-dichlorobenzene (ortho-dichlorobenzene) 95-50-1 tri (trichloroethylene) 79-01-6 ortho-dichlorobenzene (F002) 95-50-1 tri-clene (trichloroethylene) 79-01-6 oxitol (2-ethoxyethanol) 110-80-5 trichloran (trichloroethylene) 79-01-6 p-cresol (D025) 106-44-5 trichloren (trichloroethylene) 79-01-6 p-cresylic acid (p-cresol) 106-44-5 trichloroethene (trichloroethylene) 79-01-6 p-dichlorobenzene (1,4-dichlorobenzene) 106-46-7 trichloroethylene (F001; D040) 79-01-6 para-dichlorobenzene (1,4-dichlorobenzene) 106-46-7 trichlorofluoromethane (F002) 75-69-4 pce (tetrachloroethylene) 127-18-4 trichloromethane (chloroform) 67-66-3 trichloromonofluoromethane pcp (pentachlorophenol) 87-86-5 75-69-4 (trichlorofluoromethane) pdb (1,4-dichlorobenzene) 106-46-7 tricresol (cresol) 1319-77-3 penta (pentachlorophenol) 87-86-5 trielene (trichloroethylene) 79-01-6 penachlorol (pentachlorophenol) 87-86-5 trilene (trichloroethylene) 79-01-6 pentachlorophenol (D037) 87-86-5 triline (trichloroethylene) 79-01-6 perc (tetrachloroethylene) 127-18-4 trimar (trichloroethylene) 79-01-6 perclene (tetrachloroethylene) 127-18-4 trinoxol (2,4-d) 94-75-7 perchlorobenzene (hexachlorobenzene) 118-74-1 vc (vinyl chloride) 75-01-4 perchloroethane (hexachloroethane) 67-72-1 vinyl chloride (D043) 75-01-4 perchloroethene (tetrachloroethene) 127-18-4 vinyl trichloride (1,1,2-trichloroethane) 79-00-5 perchloroethylene (tetrachloroethylene) 127-18-4 westrosol (trichloroethylene) 79-01-6 perchloromethane (carbon tetrachloride) 56-23-5 xylene (F003) 1330-20-7 phenyl chloride (chlorobenzene) 108-90-7 xylol (xylene) 1330-20-7 phenyl ethane (ethyl benzene) 100-41-4 ww.epchc.org E-Mail: [email protected] AN AFFIRMATIVE ACTION - EQUAL OPPORTUNITY EMPLOYER Printed on recycled paper Page 2 F001-5 Codes: If you see these codes, your spent solvent may be a Listed Hazardous Waste. If a solvent is listed, it means the spent solvent itself, plus anything it touches, contaminates, or that is derived from it is also Listed Hazardous Waste. Spent solvents containing F001, F002, F004, or F005 ingredients are both Toxic and Ignitable. Rags and absorbents that become contaminated with these are common hazardous wastes. However, F003 ingredients are only Ignitable. If your rags or absorbents are contaminated with these, but no other hazardous waste, they may be allowed to dry and disposed as a solid waste. D004-43 Codes: Your waste is hazardous if it contains one or more of these Toxicity Characteristic chemicals at or above the regulatory level for each, as defined in the 40 CFR Part 261.24 Table 1. These include some solvents, heavy metals, pesticides, and other Toxic chemicals. Wastes contaminated with these chemicals may require laboratory analysis to determine whether or not they are Hazardous Waste. The Environmental Protection Commission (EPC) maintains this list of chemical names and synonyms as a service to the public and Hillsborough County businesses. The information is not necessarily a complete list of names and/or synonyms. Users of this list are responsible for ensuring that their own wastes are managed according to federal, state, and local regulations, regardless of whether or not its constituents appear on this list. This list is updated periodically and is subject to change without notice. The EPC encourages users to offer feedback on any information it distributes. .
Load more

Recommended publications
  • Problem Formulation of the Risk Evaluation for Perchloroethylene (Ethene, 1,1,2,2-Tetrachloro)
    EPA Document# EPA-740-R1-7017 May 2018 DRAFTUnited States Office of Chemical Safety and Environmental Protection Agency Pollution Prevention Problem Formulation of the Risk Evaluation for Perchloroethylene (Ethene, 1,1,2,2-Tetrachloro) CASRN: 127-18-4 May 2018 TABLE OF CONTENTS ABBREVIATIONS ............................................................................................................................ 8 EXECUTIVE SUMMARY .............................................................................................................. 11 1 INTRODUCTION .................................................................................................................... 14 1.1 Regulatory History ..................................................................................................................... 16 1.2 Assessment History .................................................................................................................... 16 1.3 Data and Information Collection ................................................................................................ 18 1.4 Data Screening During Problem Formulation ............................................................................ 19 2 PROBLEM FORMULATION ................................................................................................. 20 2.1 Physical and Chemical Properties .............................................................................................. 20 2.2 Conditions of Use ......................................................................................................................
    [Show full text]
  • Toxicological Profile for Tetrachloroethylene
    TETRACHLOROETHYLENE 263 6. POTENTIAL FOR HUMAN EXPOSURE 6.1 OVERVIEW Tetrachloroethylene has been identified in at least 949 of the 1,854 hazardous waste sites that have been proposed for inclusion on the EPA National Priorities List (NPL) (ATSDR 2017a). However, the number of sites evaluated for tetrachloroethylene is not known. The frequency of these sites can be seen in Figure 6-1. Of these sites, 943 are located within the United States, 3 are located in the Commonwealth of Puerto Rico (not shown), 1 is located in Guam (not shown), and 1 is located in the Virgin Islands (not shown). Tetrachloroethylene is a VOC that is widely distributed in the environment. It is released to the environment via industrial emissions and from building and consumer products. Releases are primarily to the atmosphere. However, the compound is also released to surface water and land in sewage sludges and in other liquid and solid waste, where its high vapor pressure and Henry's law constant usually result in its rapid volatilization to the atmosphere. Tetrachloroethylene has relatively low solubility in water and has medium-to-high mobility in soil; thus, its residence time in surface environments is not expected to be more than a few days. However, it persists in the atmosphere for several months and can last for decades in the groundwater. Background tetrachloroethylene levels in outdoor air are typically <1 μg/m3 (0.15 ppb) for most locations (EPA 2013h, 2018); however, indoor air at source dominant facilities (e.g., dry cleaners) has been shown to have levels >1 mg/m3 (Chiappini et al.
    [Show full text]
  • Reactions of Benzene & Its Derivatives
    Organic Lecture Series ReactionsReactions ofof BenzeneBenzene && ItsIts DerivativesDerivatives Chapter 22 1 Organic Lecture Series Reactions of Benzene The most characteristic reaction of aromatic compounds is substitution at a ring carbon: Halogenation: FeCl3 H + Cl2 Cl + HCl Chlorobenzene Nitration: H2 SO4 HNO+ HNO3 2 + H2 O Nitrobenzene 2 Organic Lecture Series Reactions of Benzene Sulfonation: H 2 SO4 HSO+ SO3 3 H Benzenesulfonic acid Alkylation: AlX3 H + RX R + HX An alkylbenzene Acylation: O O AlX H + RCX 3 CR + HX An acylbenzene 3 Organic Lecture Series Carbon-Carbon Bond Formations: R RCl AlCl3 Arenes Alkylbenzenes 4 Organic Lecture Series Electrophilic Aromatic Substitution • Electrophilic aromatic substitution: a reaction in which a hydrogen atom of an aromatic ring is replaced by an electrophile H E + + + E + H • In this section: – several common types of electrophiles – how each is generated – the mechanism by which each replaces hydrogen 5 Organic Lecture Series EAS: General Mechanism • A general mechanism slow, rate + determining H Step 1: H + E+ E El e ctro - Resonance-stabilized phile cation intermediate + H fast Step 2: E + H+ E • Key question: What is the electrophile and how is it generated? 6 Organic Lecture Series + + 7 Organic Lecture Series Chlorination Step 1: formation of a chloronium ion Cl Cl + + - - Cl Cl+ Fe Cl Cl Cl Fe Cl Cl Fe Cl4 Cl Cl Chlorine Ferric chloride A molecular complex An ion pair (a Lewis (a Lewis with a positive charge containing a base) acid) on ch lorine ch loronium ion Step 2: attack of
    [Show full text]
  • Summary of Gas Cylinder and Permeation Tube Standard Reference Materials Issued by the National Bureau of Standards
    A111D3 TTbS?? o z C/J NBS SPECIAL PUBLICATION 260-108 o ^EAU U.S. DEPARTMENT OF COMMERCE/National Bureau of Standards Standard Reference Materials: Summary of Gas Cylinder and Permeation Tube Standard Reference Materials Issued by the National Bureau of Standards QC 100 U57 R. Mavrodineanu and T. E. Gills 260-108 1987 m he National Bureau of Standards' was established by an act of Congress on March 3, 1901. The Bureau's overall goal i s t0 strengthen and advance the nation's science and technology and facilitate their effective application for public benefit. To this end, the Bureau conducts research to assure international competitiveness and leadership of U.S. industry, science arid technology. NBS work involves development and transfer of measurements, standards and related science and technology, in support of continually improving U.S. productivity, product quality and reliability, innovation and underlying science and engineering. The Bureau's technical work is performed by the National Measurement Laboratory, the National Engineering Laboratory, the Institute for Computer Sciences and Technology, and the Institute for Materials Science and Engineering. The National Measurement Laboratory Provides the national system of physical and chemical measurement; • Basic Standards 2 coordinates the system with measurement systems of other nations and • Radiation Research furnishes essential services leading to accurate and uniform physical and • Chemical Physics chemical measurement throughout the Nation's scientific community, • Analytical Chemistry industry, and commerce; provides advisory and research services to other Government agencies; conducts physical and chemical research; develops, produces, and distributes Standard Reference Materials; provides calibration services; and manages the National Standard Reference Data System.
    [Show full text]
  • 1,2-DICHLOROETHANE 1. Exposure Data
    1,2-DICHLOROETHANE Data were last reviewed in IARC (1979) and the compound was classified in IARC Monographs Supplement 7 (1987a). 1. Exposure Data 1.1 Chemical and physical data 1.1.1 Nomenclature Chem. Abstr. Serv. Reg. No.: 107-06-2 Chem. Abstr. Name: 1,2-Dichloroethane IUPAC Systematic Name: 1,2-Dichloroethane Synonym: Ethylene dichloride 1.1.2 Structural and molecular formulae and relative molecular mass Cl CH2 CH2 Cl C2H4Cl2 Relative molecular mass: 98.96 1.1.3 Chemical and physical properties of the pure substance (a) Description: Colourless liquid with a pleasant odour (Budavari, 1996) (b) Boiling-point: 83.5°C (Lide, 1995) (c) Melting-point: –35.5°C (Lide, 1995) (d) Solubility: Slightly soluble in water; miscible with ethanol, chloroform and diethyl ether (Lide, 1995; Budavari, 1996) (e) Vapour pressure: 8 kPa at 20°C (Verschueren, 1996) (f) Flash-point: 18°C, open cup (Budavari, 1996) (g) Conversion factor: mg/m3 = 4.0 × ppm 1.2 Production and use World production capacities in 1988 for 1,2-dichloroethane have been reported as follows (thousand tonnes): North America, 9445; western Europe, 9830; Japan, 3068; and other, 8351 (Snedecor, 1993). Production in the United States has been reported as follows (thousand tonnes): 1983, 5200; 1990, 6300; 1991, 6200; 1992, 6900; 1993, 8100 (United States National Library of Medicine, 1997). The total annual production in Canada in 1990 was estimated to be 922 thousand tonnes; more than 1000 thousand tonnes were produced in the United Kingdom in 1991 (WHO, 1995). –501– 502 IARC MONOGRAPHS VOLUME 71 1,2-Dichloroethane is used primarily in the production of vinyl chloride; 99% of total demand in Canada, 90% in Japan and 88% of total production in the United States are used for this purpose.
    [Show full text]
  • BENZENE AS a LARVICIDE for SCREW WORMS1 the Larval Stage
    BENZENE AS A LARVICIDE FOR SCREW WORMS1 By D. C. PARMAN Assistant Entomologist, Investigations of Insects Affecting the Health of Animals, Bureau of Entomology, United States Department of Agriculture INTRODUCTION The larval stage of CocMiomyia macellaria Fab., generally known amonff stock raisers in the Southwest as the screw worm, causes con- siderable loss to the livestock industry, estimated as high as $5,000,000 in some years. It has been apparent that the larvicides used to kill the worms are either toxic to the animal or at least in most cases detrimental to the healing of the wounds. This toxicity was at first attributed to the screw worm, but as many cases were ob- served where the animal was practically consumed by the larvae and still lived until the loss of olood or injury to some vital organ brought de^th, it was surmised that the treatments with larvicides were the cause of many deaths. During the summer of 1916 syste- matic work was begun to find a more efficient larvicide than the phenols and chloroform which were generally used. At first an attempt was made to add something to these larvicides to counteract the toxic properties. As this was not successful it was deemed best to look for a chemical that might be used with more satis- factory results. Several chemical groups were studied for possible larvicides. EXPERIMENTAL PROCEDURE All available chemicals with possible larvicidal value were selected for laboratory tests to determine whether they would kill the larvae of the screw-worm fly. The first tests were made by pouring the chemical on a number of larvae in a tube, or dusting on just enough to cover the larvae.
    [Show full text]
  • Reactions of Aromatic Compounds Just Like an Alkene, Benzene Has Clouds of  Electrons Above and Below Its Sigma Bond Framework
    Reactions of Aromatic Compounds Just like an alkene, benzene has clouds of electrons above and below its sigma bond framework. Although the electrons are in a stable aromatic system, they are still available for reaction with strong electrophiles. This generates a carbocation which is resonance stabilized (but not aromatic). This cation is called a sigma complex because the electrophile is joined to the benzene ring through a new sigma bond. The sigma complex (also called an arenium ion) is not aromatic since it contains an sp3 carbon (which disrupts the required loop of p orbitals). Ch17 Reactions of Aromatic Compounds (landscape).docx Page1 The loss of aromaticity required to form the sigma complex explains the highly endothermic nature of the first step. (That is why we require strong electrophiles for reaction). The sigma complex wishes to regain its aromaticity, and it may do so by either a reversal of the first step (i.e. regenerate the starting material) or by loss of the proton on the sp3 carbon (leading to a substitution product). When a reaction proceeds this way, it is electrophilic aromatic substitution. There are a wide variety of electrophiles that can be introduced into a benzene ring in this way, and so electrophilic aromatic substitution is a very important method for the synthesis of substituted aromatic compounds. Ch17 Reactions of Aromatic Compounds (landscape).docx Page2 Bromination of Benzene Bromination follows the same general mechanism for the electrophilic aromatic substitution (EAS). Bromine itself is not electrophilic enough to react with benzene. But the addition of a strong Lewis acid (electron pair acceptor), such as FeBr3, catalyses the reaction, and leads to the substitution product.
    [Show full text]
  • Formation of Nitrous Oxide
    1461 No. 5069 DECEMBER 24. 1966 NATURE E-+ CCI. --->- ECC1 3 + Cl- Formation of Nitrous Oxide THE mechanism of formation of nitrous oxide from am­ The tightly bound .CCI3 group will not be removable in monium nitrate is attributable to the recognized thermal the normal biochemical reaction and the enzyme molecule dissociation of ammonium salts followed in this instance will be inactivated. by nitration of ammonia and decomposition of the ensuing This process of enzyme inactivation could, in principle, nitramide. The mechanism of this latter stage has been account for the toxicity of carbon tetrachloride and studied by various workers, notably by Marlies and La similar compounds and also of many insecticides. The Merl. Further, the decomposition of methyl nitramido postulated mechanism would also explain the observation to tho oxide and methyl alcohol is on record 2. by Butlerl3 that carbon tetrachloride is reduced in vivo As the nitration process, for example, of benzene, is to chloroform. Thus a proportion of .CCls radicals may commonly accompanied by some oxidation, the possibility react with sites other than the enzyme and abstract, of its OCClllTcnce in the preparation of nitrous oxide with for example, a hydrogen atom from a hydroxyl group or formation of nitrogen peroxide is not surprising and from a sulphydryl group. The latter exchange does technically well recognized. It has also recently been the appear to be possible from energy considerations. subject of public concern. D(RS-H) = 89 kcalJmole (ref. 14), .J. KENNER D(CI3G-H) = 91·4 kcalJmole (ref. 9) 41 Burlington Road, I have found that the activation energy of the electron Withington, capture reaction in chloroform vapour Manchester 20.
    [Show full text]
  • Tetrachloroethylene Facts
    TETRACHLOROETHYLENE CAS # 127-18-4 Agency for Toxic Substances and Disease Registry ToxFAQs September 1997 This fact sheet answers the most frequently asked health questions (FAQs) about tetrachloroethylene. For more information, call the ATSDR Information Center at 1-888-422-8737. This fact sheet is one in a series of summaries about hazardous substances and their health effects. It’s important you understand this information because this substance may harm you. The effects of exposure to any hazardous substance depend on the dose, the duration, how you are exposed, personal traits and habits, and whether other chemicals are present. HIGHLIGHTS: Tetrachloroethylene is a manufactured chemical used for dry cleaning and metal degreasing. Exposure to very high concentrations of tetrachloroethylene can cause dizziness, headaches, sleepiness, confusion, nausea, difficulty in speaking and walking, unconsciousness, and death. Tetrachloroethylene has been found in at least 771 of the 1,430 National Priorities List sites identified by the Environmental Protection Agency (EPA). What is tetrachloroethylene? How might I be exposed to tetrachloroethylene? (Pronounced tµt”r…-klôr“ ½-µth“…-l¶n”) q When you bring clothes from the dry cleaners, they will release small amounts of tetrachloroethylene into the air. Tetrachloroethylene is a manufactured chemical that is q widely used for dry cleaning of fabrics and for metal-degreas- When you drink water containing tetrachloroethylene, you are exposed to it. ing. It is also used to make other chemicals and is used in some consumer products. Other names for tetrachloroethylene include perchloroet- How can tetrachloroethylene affect my health? hylene, PCE, and tetrachloroethene. It is a nonflammable High concentrations of tetrachloroethylene (particularly liquid at room temperature.
    [Show full text]
  • Optimization Study on the Azeotropic Distillation Process for Isopropyl Alcohol Dehydration
    Korean J. Chem. Eng., 23(1), 1-7 (2006) Optimization study on the azeotropic distillation process for isopropyl alcohol dehydration Jungho Cho and Jong-Ki Jeon*,† Department of Chemical Engineering, Dong Yang University, 1, Kyochon-dong, Poongki-eup, Youngju, Gyeongbuk 750-711, Korea *Department of Chemical Engineering, Kongju National University, 182, Shinkwan-dong, Gongju, Chungnam 314-701, Korea (Received 9 August 2005 • accepted 26 November 2005) Abstract−Modeling and optimization work was performed using benzene as an entrainer to obtain a nearly pure an- hydrous isopropyl alcohol product from dilute aqueous IPA mixture through an azeotropic distillation process. NRTL liquid activity coefficient model and PRO/II with PROVISION 6.01, a commercial process simulator, were used to simulate the overall azeotropic distillation process. We determined the total reboiler heat duties as an objective function and the concentration of IPA at concentrator top as a manipulated variable. As a result, 38.7 mole percent of IPA at concentrator top gave the optimum value that minimized the total reboiler heat duties of the three distillation columns. Key words: Azeotropic Distillation, Entrainer, NRTL Liquid Activity Coefficient Model, Simulation, Optimization INTRODUCTION using special distillation. One is to utilize an azeotropic distillation process using benzene or cyclohexane as an entrainer [Font et al., An anhydrous isopropyl alcohol (IPA) product with purity over 2003; Tao et al., 2003; Al-Amer, 2000; Fele et al., 2000] and the 99.9% by weight has been widely used as a raw material of paint other is an extractive distillation process using ethylene glycol as a or ink products and as a solvent in electronic and medicine indus- solvent [Ligero and Ravagnani, 2003; Pinto et al., 2000].
    [Show full text]
  • The Detailed Kinetics of the Partial Oxidation Reactions: Benzene/Butane to Maleic Anhydride Ethylene to Ethylene Oxide
    The Detailed Kinetics of the Partial Oxidation Reactions: Benzene/Butane to Maleic Anhydride Ethylene to Ethylene Oxide Ken Waugh Emeritus Professor of Physical Chemistry ICI Central Instruments Research Lab Bozedown House Berkshire The Oxidation of Benzene to Maleic Anhydride Over Vanadium Pentoxide D(V‐O) = 600 kJmol‐1 D A Dowden mechanism of benzene oxidation to MA using molecularly adsorbed O2 Maleic anhydride temperature programmed desorption spectra from V2O5: adsorption temperature (a) 135, (b) 150, (c) 160, (d) 170, (e) 180, (f) 190, (g) 200 C Benzene temperature programmed desorption spectra: curve (a) benzene, curve (b) maleic anhydride Desorption spectra following the adsorption of benzene at (a) 75, (b) 90 and (c) 100 C. Curves 1and 2 are benzene; curve (c) is maleic anhydride Activation Energy 31 kJmol‐1 The Oxidation of n‐butane to Maleic Anhydride • Anaerobic Selectivity 80% The (100) face of (VO)2P2O7 –the active face Recirculating Solids Reactor for n‐butane Oxidation to Maleic Anhydride ‐ DuPont Schematic Representation of the Mars and van Krevelen Mechanism Oxygen desorption from (VO)2P2O7 Anaerobic Temperature Programmed Oxidation of n‐ butane over the (VO)2P2O7 Catalyst Anaerobic Temperature Programmed Oxidation of but‐1‐ene over the (VO)2P2O7 Catalyst Anaerobic Temperature Programmed Oxidation of but‐1,3‐diene over the (VO)2P2O7 Catalyst Side View of n‐butane Adsorbed End‐on Identification of the Origins of Selectivity in Ethylene Epoxidation on Promoted and Unpromoted Ag/α‐Al2O3 Catalysts: a detailed kinetic, mechanistic
    [Show full text]
  • A Toxic Threat
    A Toxic Threat FACT SHEET Government Must Act Now on PFAS Contamination at Military Bases HIGHLIGHTS In May 2018, the Union of Concerned Scientists (UCS) released documents ob- Per- and polyfluoroalkyl substances, tained through the Freedom of Information Act that revealed that Trump admin- known as PFAS, are a group of synthetic istration officials had blocked the release of a draft government toxicology report on per- and polyfluoroalkyl substances, known as PFAS. These chemicals have compounds used in products ranging from been linked to cancers, developmental and reproductive toxicity, thyroid disease, firefighting foam to nonstick cookware. immune system toxicity, and other health effects (ATSDR 2018). The documents These chemicals have been linked with revealed that the Trump administration was holding up the release of the scien- diseases including liver damage, kidney tific report about the hazards these chemicals posed because officials feared rais- cancer, and ulcerative colitis. This fact sheet ing public health concerns the administration preferred to ignore. As one Trump maps 131 active and formerly active US administration official privately warned in an email, the report’s release threat- ened to lead to a “public relations nightmare” (Halpern 2018). military installations to determine where After significant bipartisan congressional pressure followed public exposure PFAS contamination of groundwater and of this suppression, the report was released in June 2018 by the Agency for Toxic drinking water exceeds new Agency for Substances and Disease Registry (ASTDR), a division of the Centers for Disease Toxic Substances and Disease Registry risk Control and Prevention at the US Department of Health and Human Services.
    [Show full text]