Tetrachloroethylene: Difference between revisions

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			{{short description\|Chemical compound in very wide use}}
	{{Chembox new
			{{use dmy dates \|date=September 2022}}
	\| Name = Tetrachloroethylene
			{{chembox
	\| ImageFileL1 = Tetrachloroethylene.svg
			\| Verifiedfields = changed
	\| ImageSizeL1 = 100px
			\| Watchedfields = changed
	\| ImageNameL1 = Tetrachloroethylene
			\| verifiedrevid = 433348706
	\| ImageFileR1 = Tetrachloroethylene-3D-vdW.png
			\| Name = Tetrachloroethylene
	\| ImageSizeR1 = 120px
	\| ~~ImageNameR1~~ = Tetrachloroethylene		\| ImageFileL1 = Tetrachloroethylene.svg
			\| ImageNameL1 = Tetrachloroethylene
	\| IUPACName = tetrachloroethene
			\| ImageFileR1 = Tetrachloroethylene-3D-vdW.png
	\| OtherNames = perchloroethene<br />perchloroethylene<br />perc, PCE
			\| ImageNameR1 = Tetrachloroethylene
	\| Section1 = {{Chembox Identifiers
			\| ImageCaptionR1 = {{legend\|black\|], C}}{{legend\|lime\|], Cl}}
	\| SMILES = C(=C(Cl)Cl)(Cl)Cl
			\| ImageFile2 = Tetrakloroetilen2.jpg
	\| CASNo = 127-18-4
	\| ~~EINECS~~ = ~~204-825-9~~		\| ImageSize2 = 150
			\| PIN = Tetrachloroethene
	\| RTECS = KX3850000
			\| OtherNames = Carbon bichloride; Carbon dichloride (''Carboneum Dichloratum''); Ethylene tetrachloride; Perchlor; Perchloroethene; Perchloroethylene;
			\|Section1={{Chembox Identifiers
			\| Abbreviations= PCE; Perc; Per
			\| CASNo_Ref = {{cascite\|correct\|CAS}}
			\| CASNo = 127-18-4
			\| Beilstein = 1304635
			\| ChEBI_Ref = {{ebicite\|changed\|EBI}}
			\| ChEBI = 17300
			\| ChEMBL_Ref = {{ebicite\|correct\|EBI}}
			\| ChEMBL = 114062
			\| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}}
			\| ChemSpiderID = 13837281
			\| EINECS = 204-825-9
			\| Gmelin = 101142
			\| KEGG_Ref = {{keggcite\|correct\|kegg}}
			\| KEGG = C06789
			\| PubChem = 31373
			\| RTECS = KX3850000
			\| UNII_Ref = {{fdacite\|correct\|FDA}}
			\| UNII = TJ904HH8SN
			\| UNNumber = 1897
			\| InChI = 1/C2Cl4/c3-1(4)2(5)6
			\| InChIKey = CYTYCFOTNPOANT-UHFFFAOYAO
			\| StdInChI_Ref = {{stdinchicite\|correct\|chemspider}}
			\| StdInChI = 1S/C2Cl4/c3-1(4)2(5)6
			\| StdInChIKey_Ref = {{stdinchicite\|correct\|chemspider}}
			\| StdInChIKey = CYTYCFOTNPOANT-UHFFFAOYSA-N
			\| SMILES = ClC(Cl)=C(Cl)Cl
	}}		}}
	\| Section2 = {{Chembox Properties		\|Section2={{Chembox Properties
			\| C=2 \| Cl=4
	\| Formula = C<sub>2</sub>Cl<sub>4</sub>
	\| ~~MolarMass~~ = ~~165.8~~ g/mol		\| MolarMassUnit = g/mol
	\| Appearance = Clear, colorless liquid		\| Appearance = Clear, very refractive, colorless liquid
			\| Odor = Mild, sharp and sweetish<ref name=PGCH/>
	\| Density = 1.622 g/cm<sup>3</sup>, liquid
			\| Density = 1.622{{nbsp}}g/cm<sup>3</sup>
	\| Solubility = 0.015 g/100 ml (20 °C)
			\| Solubility = 0.15{{nbsp}}g/L (25{{nbsp}}°C)
	\| MeltingPt = −19 °C (254 K)
	\| ~~BoilingPt~~ = ~~121~~.1 °C ~~(394 K)~~		\| MeltingPtC = -22.0 to -22.7
			\| BoilingPtC = 121.1
	\| Viscosity = 0.89 ] at 25 °C
			\| Viscosity = 0.89{{nbsp}}] at 25{{nbsp}}°C
			\| VaporPressure = 14{{nbsp}}mmHg (20{{nbsp}}°C)<ref name=PGCH/>
			\| MagSus = −81.6·10<sup>−6</sup>{{nbsp}}cm<sup>3</sup>/mol
			\| RefractIndex = 1.505
	}}		}}
	\| Section7 = {{Chembox Hazards		\|Section7={{Chembox Hazards
			\| NFPA-F = 0 \| NFPA-H = 2 \| NFPA-R = 0 \| NFPA-S =
	\| ExternalMSDS =
			\| NFPA_ref = <ref name="pubchem">{{cite web \|url= https://pubchem.ncbi.nlm.nih.gov/compound/31373#section=NFPA-Hazard-Classification \|title= Compound Summary: Tetrachloroethylene \|publisher=], US National Library of Medicine\|date=21 September 2024 \|access-date= 24 September 2024}}</ref>
	\| MainHazards = Harmful (Xn),<br />Dangerous for<br /> the environment (N)
			\| MainHazards = Inhalation of vapours can cause anaesthesia and respiratory irritation. Causes irritation in contact with skin and eyes with no residual injury.
	\| FlashPt = Not flammable
			\| ExternalSDS =
	\| RPhrases = 40-51/53
			\| FlashPt = Not flammable
	\| SPhrases = 23-36/37-61
			\| GHSPictograms = {{GHS08}}{{GHS09}}
	}}
			\| GHSSignalWord = Warning
	\| Section8 = {{Chembox Related
			\| HPhrases = {{H-phrases\|351\|411}}
	\| Function = Related ]s
			\| PPhrases = {{P-phrases\|201\|202\|273\|281\|308+313\|391\|405\|501}}
	\| OtherFunctn = ]<br /> ]
			\| IDLH = Ca <ref name=PGCH>{{PGCH\|0599}}</ref>
	\| OtherCpds = ]<br /> ]<br /> ]
			\| REL = Ca Minimize workplace exposure concentrations.<ref name=PGCH/>
			\| PEL = TWA 100{{nbsp}}ppm<br/>C 200{{nbsp}}ppm (for 5 minutes in any 3-hour period), with a maximum peak of 300{{nbsp}}ppm<ref name=PGCH/>
			\| LD50 = 3420 mg/kg (oral, rat)<ref></ref><br>2629 mg/kg (oral, rat), >10000 mg/kg (dermal, rat)<ref></ref>
			\| LC50 = 4000{{nbsp}}ppm (rat, 4{{nbsp}}hr)<br/>5200{{nbsp}}ppm (mouse, 4{{nbsp}}hr)<br/>4964{{nbsp}}ppm (rat, 8{{nbsp}}hr)<ref>{{IDLH\|127184\|Tetrachloroethylene}}</ref>
	}}		}}
			\|Section8={{Chembox Related
			\| OtherFunction_label = analogous ]s
			\| OtherFunction = ] <br /> ]<br />]
			\| OtherCompounds = ]<br />]<br />]<br />]}}
	}}		}}

	'''Tetrachloroethylene''', also known ~~under~~ ~~its~~ ~~systematic~~ ~~name~~ '''~~tetrachloroethene~~''' ~~and~~ as '''~~perchloroethylene~~''', '''~~perchloroethene~~''', '''~~perc~~''', and '''PCE''', is a ] with the formula ~~Cl<sub>2</sub>C=CCl<sub>2</sub>~~. It is a ~~colourless~~ liquid widely used for ] of fabrics, ~~hence~~ it is ~~sometimes~~ ~~called~~ ~~"dry-cleaning~~ ~~fluid~~." It has a sweet odor detectable by most people at a concentration of ~~1 part per million (1~~ ppm~~). Worldwide production was about 1 megaton in 1985~~.<ref name=~~Ullmann~~>M. ~~Rossberg~~ et ~~al.~~ ~~“Chlorinated~~ ~~Hydrocarbons”~~ in ~~Ullmann’s Encyclopedia~~ of Industrial ~~Chemistry~~ ~~2006,~~ ~~Wiley-VCH,~~ ~~Weinheim.~~ ~~{{DOI~~\|10.~~1002~~/~~14356007~~.~~a06~~ ~~233.pub2~~}}</ref>		'''Tetrachloroethylene''', also known as '''perchloroethylene'''{{efn\|Previously spelt as '''perchlorethylene'''}} or under the systematic name '''tetrachloroethene''', and abbreviations such as '''perc''' (or '''PERC'''), and '''PCE''', is a ] with the formula {{chem2\|Cl2C\dCCl2}}. It is a non-flammable, stable, colorless and heavy liquid widely used for ] of fabrics. It also has its uses as an effective automotive ]. It has a mild sweet, sharp odor, detectable by most people at a concentration of 50 ppm.<ref name=browning>{{cite book \|first=Ethel \|last=Browning \|author-link=Ethel Browning (toxicologist) \|title=Toxicity of Industrial Organic Solvents \|year=1953 \|publisher=Chemical Publishing \|section-url=https://archive.org/details/cftri.3112toxicityofindust0000ethe/page/182/mode/1up \|pages=182–185 \|chapter=Perchloroethylene}}</ref>

			Tetrachloroethylene is regarded as a toxic substance, a ], and an ].<ref name=pubchem/><ref name="tox">{{cite web \|author=US Agency for Toxic Substances and Disease Registry \|title=Toxicological Profile for Tetrachloroethylene \|url=https://www.ncbi.nlm.nih.gov/books/NBK591314/ \|publisher=US National Library of Medicine \|access-date=23 September 2024 \|date=June 2019}}</ref> In 2020, the United States ] stated that "tetrachloroethylene exposure may harm the nervous system, liver, kidneys, and reproductive system, and may be harmful to unborn children", and reported that numerous ] agencies regard it as a ].<ref name="epa">{{cite web \|title=Public Health Statement for Tetrachloroethylene (PERC) \|url=https://wwwn.cdc.gov/TSP/PHS/PHS.aspx?phsid=263&toxid=48 \|publisher=US Environmental Protection Agency \|access-date=23 September 2024 \|date=22 June 2020}}</ref>
	==Production==
	] first synthesized tetrachloroethene in 1821 by thermal decomposition of ] into tetrachloroethene and ].
	Most tetrachloroethene is produced by high temperature chlorinolysis of light hydrocarbons. The method is related to Faraday's discovery since hexachloroethane is generated and thermally decomposes.<ref name=Ullmann/> Side products include ], ], and ].

			==History and production==
	Several other methods have been developed. When 1,2-dichloroethane is heated to 400 °C with ], tetrachloroethene is produced by the ]:
			French ] ] first synthesized tetrachloroethylene in 1839 by thermal decomposition of ] following ]'s 1820 synthesis of protochloride of carbon (carbon tetrachloride).
	:] + 3 Cl<sub>2</sub> → Cl<sub>2</sub>C=CCl<sub>2</sub> + 4 ]
			:{{chem2\|C2Cl6 → C2Cl4 + Cl2}}
	This reaction can be ] by a mixture of ] and ], or by activated ]. ] is a major byproduct of the reaction, and since both are salable commercial chemicals, typical industrial practice is to collect both products and then separate them by ].
			Faraday was previously falsely credited for the synthesis of tetrachloroethylene, which in reality, was ].{{Primary source inline\|date=October 2024}} While trying to make Faraday's "protochloride of carbon", Regnault found that his compound was different from Faraday's. Victor Regnault stated "According to Faraday, the chloride of carbon boiled around {{convert\|70\|C\|F}} to {{convert\|77\|C\|F}} degrees Celsius but mine did not begin to boil until {{convert\|120\|C\|F}}".<ref>V. Regnault (1839) (On the chlorides of carbon CCl and CCl<sup>2</sup>), ''Annales de Chimie et de Physique'', vol. 70, pages 104–107. Reprinted in German as: {{cite journal
			\|journal =Annalen der Pharmacie
			\|volume = 30
			\|issue = 3
			\|year = 1839
			\|title = Ueber die Chlorverbindungen des Kohlenstoffs, C2Cl2 und CCl2
			\|author = V. Regnault
			\|doi = 10.1002/jlac.18390300310
			\|pages =350–352
			\|url = https://zenodo.org/record/1426937
			}}</ref>

			Tetrachloroethylene can be made by passing chloroform vapour through a red-hot tube, the side products include ] and ], as reported in 1886.<ref>] and ], ], 1886, p. 628</ref>

			Most tetrachloroethylene is produced by high-temperature chlorinolysis of light hydrocarbons. The method is related to Faraday's method since hexachloroethane is generated and thermally decomposes.<ref name=Ullmann/> Side products include ], ], and ].

			Several other methods have been developed. When ] is heated to 400 °C with ], tetrachloroethylene is produced:
			:{{chem2\|ClCH2CH2Cl + 3 Cl2 → Cl2C\dCCl2 + 4 HCl}}
			This reaction can be ] by a mixture of ] and ] or by activated ]. ] is a major byproduct, which is separated by ].

			Worldwide production was about {{convert\|1\|e6MT}} in 1985.<ref name=Ullmann>{{Ullmann \|last1=Rossberg \|first1=M. \|last2=Lendle \|first2=W. \|last3=Pfleiderer \|first3=G. \|last4=Tögel \|first4=A. \|last5=Dreher \|first5=E.-L. \|last6=Langer \|first6=E. \|last7=Rassaerts \|first7=H. \|last8=Kleinschmidt \|first8=P. \|last9=Strack \|first9=H. \|last10=Cook \|first10=R. \|last11=Beck \|first11=U. \|last12=Lipper \|first12=K.-A. \|last13=Torkelson \|first13=T.R. \|last14=Löser \|first14=E. \|last15=Beutel \|first15=K.K. \|last16=Mann \|first16=T. \|title=Chlorinated Hydrocarbons \|doi=10.1002/14356007.a06_233.pub2}}</ref>

			Although in very small amounts, tetrachloroethylene occurs naturally in volcanoes along with ].<ref>{{cite journal \| doi = 10.1021/np50088a001 \| last = Gribble \|first = G. W. \| title = Naturally occurring organohalogen compounds – A comprehensive survey \| journal = Progress in the Chemistry of Organic Natural Products \| year = 1996 \| volume = 68 \| pages = 1–423 \| pmid = 8795309 \| issue = 10}}</ref>

	==Uses==		==Uses==
			Tetrachloroethylene is an excellent nonpolar ] for ] materials. Additionally, it is volatile, highly stable (easily recycled) and ], and has low toxicity. For these reasons, it has been widely used in ] worldwide since the 1930s. The chemist ] (1901–1991) had suggested tetrachloroethylene to be used in dry cleaning as an alternative to highly flammable dry cleaning solvents such as ].<ref name="Amos">{{Cite book \|last=Amos \|first=J. Lawrence \|title=A History of the Dow Chemical Physics Lab : the freedom to be creative \|date=1990 \|publisher=Marcel Dekker, Inc. \|editor-last=Boundy \|editor-first=Ray H. \|location=New York and Basel \|pages=71–79 \|chapter=Chlorinated solvents \|editor-last2=Amos \|editor-first2=J. Lawrence}}</ref>
	Most tetrachloroethylene is consumed as a ] used in ]. It is desirable because it dissolves many ] materials, it is volatile, highly stable, and ]. Usually as a mixture with other chlorocarbons, it is also used to degrease metal parts in the ] and other metalworking industries. It appears in a few consumer products including ]s and spot removers.

			It is also used to degrease metal parts in the automotive and other metalworking industries, usually as a mixture with other chlorocarbons. It appears in a few consumer products including ]s, aerosol preparations and spot removers.
	It is used as a solvent for proton ] scans.

	===Historical applications===		===Historical applications===
	~~Tetrachloroethene~~ was ~~also~~ extensively used as an intermediate in the manufacture of ] and related ]s~~. In the early 20th century, tetrachloroethene was the most effective available treatment for ]~~.		Tetrachloroethylene was once extensively used as an intermediate in the manufacture of ] and related ]s.

			In the early 20th century, tetrachloroethene was used for the treatment of ] infestation.<ref>{{cite journal \|last1=Young \|first1=M.D. \|last2=Jeffery \|first2=G.M. \|last3=Morehouse \|first3=W.G. \|last4=Freed \|first4=J.E. \|last5=Johnson \|first5=R.S. \|year=1960 \|title=The Comparative Efficacy of Bephenium Hydroxynaphthoate and Tetrachloroethylene against Hookworm and other Parasites of Man \|journal=American Journal of Tropical Medicine and Hygiene \|volume=9 \|issue=5 \|pages=488–491 \|doi=10.4269/ajtmh.1960.9.488 \|pmid=13787477 \|s2cid=19521345}}</ref><ref>{{cite journal \|author=<!--Staff writer(s); no by-line.--> \| title=Clinical Aspects and Treatment of the More Common Intestinal Parasites of Man (TB-33) \| journal=Veterans Administration Technical Bulletin 1946 & 1947 \| year=1948 \| volume=10 \| pages=1–14 \| url=https://books.google.com/books?id=uJWxEzwqRiMC }}</ref> In 1925, American veterinarian Maurice Crowther Hall (1881–1938), working on anthelmintics, demonstrated the effectiveness of tetrachloroethylene in the treatment of ] caused by ] infestation in humans and animals. Before Hall tested tetrachloroethylene on himself, in 1921 he discovered the powerful effect of carbon tetrachloride on intestinal parasites and was nominated for the Nobel Prize in Physiology or Medicine, but a few years later he found tetrachloroethylene to be more effective and safer.<ref>{{cite web \|title=Maurice C. Hall \|series=Special Collections \|website=] \|url=https://www.nal.usda.gov/exhibits/speccoll/items/show/8197}}</ref>
			Tetrachloroethylene treatment has played a vital role in eradicating hookworms in the United States and abroad.{{cn\|date=September 2024}} Hall's innovation was considered a breakthrough in medicine.{{cn\|date=September 2024}} It was given orally as a liquid or in capsules along with ] to get rid of the '']'' parasite in humans.<ref>{{cite book \|last=Davison \|first=Forrest Ramon \|title=Synopsis of materia medica, toxicology, and pharmacology for students and practitioners of medicine \|year=1940 \|section-url=https://archive.org/details/b32804878/page/181/mode/1up \|page=181 \|section=Tetrachlorethylene}}</ref>

			==Chemical properties and reactions==
			Tetrachloroethylene is a derivative of ] with all hydrogens replaced by ]. 14.49% of the molecular weight of tetrachloroethylene consists of ] and the remaining 85.5% is chlorine. It is the most stable compound among all chlorinated derivatives of ] and ethylene. It is resistant to hydrolysis and less corrosive than other chlorinated solvents.<ref name="Ullmann" /> It does not tend to polymerise like fluorine analogue ], {{chem2\|C2F4}}.

			Tetrachloroethylene may react violently with ] or ]s, alkalis (] and ]), ], beryllium, barium and aluminium.<ref>{{cite book \|editor1-last=Pohanish \|editor1-first=Richard P. \|title=Sittig's Handbook of Toxic and Hazardous Chemical Carcinogens \|edition=6th \|year=2012 \|publisher=Elsevier \|page=2520 \|isbn=978-1-4377-7870-0 \|section-url=https://books.google.com/books?id=RYt0Wzb60b4C&pg=PA2520 \|section=Tetrachloroethylene}}</ref>

			===Oxidation===
			] of tetrachloroethylene by ] in air produces ] and ]:
			:{{chem2\|4 C2Cl4 + 3 O2 -> 2 CCl3COCl + 4 COCl2}}
			This reaction can be halted by using amines and phenols (usually ''N''-methyl] and ''N''-methylmorpholine) as stabilisers. But the reaction can be done intentionally to produce trichloroacetyl chloride.<ref name="Ullmann"/>

			===Chlorination===
			] is formed when tetrachloroethylene reacts with ] at 50–80 °C in the presence of a small amount of ] (0.1%) as a catalyst:<ref>Oshin LA, ''Промышленные хлорорганические продукты'' (''Promyshlennyye khlororganicheskie produkty''). 1978.</ref>
			:{{chem2\|C2Cl4 + Cl2 -> C2Cl6}}
			] is produced by the reaction of tetrachloroethylene with chlorine and ] in the presence of ]:<ref>Knunyatsya IL. ''Химическая энциклопедия'' (''Khimicheskaya Entsiklopediya''). 1992. {{ISBN\|5-85270-039-8}}</ref>
			:{{chem2\|C2Cl4 + 3 HF + Cl2 -> CClF2CCl2F + 3 HCl}}

			===Nitration===
			] can be obtained by ] of tetrachloroethylene with ] (conc. {{chem2\|HNO3}} rich in ]) or ]:<ref name=argo>{{cite journal \|last1=Argo \|first1=W. L. \|last2=James \|first2=E. M. \|last3=Donnelly \|first3=J. L. \|title=Tetrachlordinitroethane \|journal=The Journal of Physical Chemistry \|date=November 1919 \|volume=23 \|issue=8 \|pages=578–585 \|doi=10.1021/j150197a004\|url=https://zenodo.org/record/1843020 }}</ref>
			:{{chem2\|Cl2CCCl2 + N2O4 -> NO2Cl2CCCl2NO2}}
			The preparation of this crystalline solid compound from Tetrachloroethylene and nitrogen tetroxide was first described by ] in 1869.<ref name=argo/>

			===Thermal decomposition===
			Tetrachloroethylene begins to thermally decompose at 400 °C, decomposition accelerates around 600 °C, and completely decomposes at 800 °C. Organic decomposition products identified were trichlorobutene, 1,3-dichloro-2-propanone, tetrachlorobutadiene, dichlorocyclopentane, dichloropentene, methyl trichloroacetate, tetrachloroacetone, tetrachloropropene, trichlorocyclopentane, trichloropentene, hexachloroethane, pentachloropropene, hexachloropropene, hexachlorobutadiene.<ref name=yasuhara>{{cite journal \|first=Akio \|last=Yasuhara \|title=Thermal decomposition of tetrachloroethylene \|journal=Chemosphere \|volume=26 \|issue=8 \|date=April 1993 \|pages=1507–1512 \|doi=10.1016/0045-6535(93)90218-T \|bibcode=1993Chmsp..26.1507Y \|s2cid=94961581}}</ref>

	==Health and safety==		==Health and safety==
			Tetrachloroethylene is considered to be a toxin.<ref name=tox/> It is identified as a ] and ].<ref name=pubchem/> Exposure to tetrachloroethylene, especially over a long term, may harm the nervous system, other ], and increase the risk of getting ].<ref name=epa/> It may also have effects on pregnancy and the ].<ref name=epa/>
	Like many ], tetrachloroethene is a ] depressant, and inhaling its vapors (particularly in closed, poorly ventilated areas) can cause dizziness, ], sleepiness, confusion, ], difficulty in speaking and walking, unconsciousness, and death.<ref></ref>

			Reports of human injury are uncommon despite its wide usage in dry cleaning and degreasing.<ref>{{Ullmann \|first1=E.-L. \|last1=Dreher \|first2=T. R. \|last2=Torkelson \|first3=K. K. \|last3=Beutel \|title=Chlorethanes and Chloroethylenes; In: Ullmann's Encyclopedia of Industrial Chemistry \|doi=10.1002/14356007.o06_o01\|date=19 November 2014\|publisher=Wiley\|location=Verlag\|isbn=9783527306732}}</ref> Although limited by its low ], tetrachloroethylene has potent anaesthetic effects upon inhalation.<ref name=epa/><ref name=foot1943>{{cite journal \|first1=Ellen B. \|last1=Foot \|first2=Virginia \|last2=Apgar \|author-link2=Virginia Apgar \|first3=Kingsley \|last3=Bishop \|title=Tetrachlorethylene as an Anesthetic Agent \|journal=] \|date=May 1943 \|volume=4 \|issue=3 \|pages=283–292 \|s2cid=70969652 \|doi=10.1097/00000542-194305000-00009 \|doi-access=free}}</ref> The risk depends on whether exposure is over minutes or hours, or over years.<ref name=epa/>
	After repeated or extended skin contact, tetrachloroethene may dissolve fats from the skin, resulting in severe skin irritation in work environments where people have been exposed to high concentrations.

			Despite the advantages of tetrachloroethylene, cancer research and government environmental agencies have called for its replacement from widespread commercial use.<ref name=epa/> It is described as a possible neurotoxicant, ] and ] and reproductive and developmental toxicant (...) a potential occupational carcinogen.<ref name=tox/><ref name=epa/><ref>{{cite journal \|doi=10.3389/fpubh.2021.638082 \|doi-access=free \|title=Perchloroethylene and Dry Cleaning: It's Time to Move the Industry to Safer Alternatives \|year=2021 \|last1=Ceballos \|first1=Diana M. \|last2=Fellows \|first2=Katie M. \|last3=Evans \|first3=Ashley E. \|last4=Janulewicz \|first4=Patricia A. \|last5=Lee \|first5=Eun Gyung \|last6=Whittaker \|first6=Stephen G. \|journal=Frontiers in Public Health \|volume=9 \|page=638082 \|pmid=33748070 \|pmc=7973082 \|s2cid=232116380}}</ref> On the other hand, dry cleaning industry emphasizes minimal risk because modern machinery use closed systems to avoid any vapour escape and to optimize recycling.<ref name=Ullmann/>
	Tetrachloroethene is a common ]. Such contamination most often results from spillage, overfilling, sewer leakage, or the illegal disposal into UIC wells (e.g. septic systems, drywells) at commercial dry cleaning facilities. Because of the mobility of PCE in groundwater, its ] at low levels, and its density (which causes it to sink below the ]), cleanup activities tend to be especially problematic compared to cleanups of oil spills.

			=== Metabolism ===
	In industry, most workers are exposed to levels lower than those causing obvious nervous system effects. The health effects of tetrachloroethene at levels typically encountered in occupational or environmental exposures have not been well established.
			Tetrachloroethylene's biological half-life is approximately 3 days.<ref name=bio/> About 98% of the inhaled tetrachloroethylene is exhaled unchanged and only about 1–3% is metabolised to ] which rapidly isomerises into ]. Trichloroacetyl chloride hydrolyses to ].<ref>Toxicological Profile for Tetrachloroethylene: Draft. (1995). U.S. Department of Health and Human Services, Public Health Service, Agency for Toxic Substances and Disease Registry.</ref><ref name=bio>{{cite book \|title=Biological Monitoring: An Introduction \|year=1993 \|editor=Shane S. Que Hee \|page=470 \|chapter=Biological Exposure Indices \|isbn=978-0-471-29083-4 \|publisher=John Wiley & Sons}}</ref>

			===Neurotoxicity===
	Results from some studies suggest that women who work in dry cleaning industries where exposures to tetrachloroethene can be high may have more ] problems and ]s than women who are not exposed. However, it is not known if tetrachloroethene was responsible for these problems because other possible causes were not considered.{{Fact\|date=August 2008}}
			Tetrachloroethylene can harm the nervous system, cause developmental deficits in children, impair vision, and increase the risk of ] diagnoses.<ref name=tox/><ref name="grand">{{cite journal \|vauthors=Grandjean P, Landrigan PJ \|title=Neurobehavioural effects of developmental toxicity \|journal=The Lancet. Neurology \|volume=13 \|issue=3 \|pages=330–8 \|date=March 2014 \|pmid=24556010 \|pmc=4418502 \|doi=10.1016/S1474-4422(13)70278-3}}</ref><ref name="aschen">{{cite journal \|vauthors=Aschengrau A, Janulewicz PA, White RF, Vieira VM, Gallagher LG, Getz KD, Webster TF, Ozonoff DM\|display-authors=3 \|title=Long-term Neurotoxic Effects of Early-life Exposure to Tetrachloroethylene-contaminated Drinking Water \|journal=Annals of Global Health \|volume=82 \|issue=1 \|pages=169–79 \|date=2016 \|pmid=27325074 \|pmc=4916338 \|doi=10.1016/j.aogh.2016.01.013}}</ref>

			=== Carcinogenicity ===
	Results of animal studies, conducted with amounts much higher than those that most people are exposed to, show that tetrachloroethene can cause ] and ] damage. Exposure to very high levels of tetrachloroethene can be toxic to the unborn pups of pregnant rats and mice. Changes in behavior were observed in the offspring of rats that breathed high levels of the chemical while they were pregnant.
			Tetrachloroethylene has been classified as "]: Probably Carcinogenic" by the ] (IARC) due to sufficient evidence in experimental animals and limited evidence in humans for non-Hodgkin lymphoma, urinary bladder cancers, and cancers of the esophagus and cervix.<ref name=iarc2014>{{Cite web \|url=https://publications.iarc.fr/Book-And-Report-Series/Iarc-Monographs-On-The-Identification-Of-Carcinogenic-Hazards-To-Humans/Trichloroethylene-Tetrachloroethylene-And-Some-Other-Chlorinated-Agents-2014 \|title=Trichloroethylene, Tetrachloroethylene, and Some Other Chlorinated Agents (IARC Monograph, Volume 106, 2014) \|website=publications.iarc.fr/ \|access-date=23 September 2024}}</ref>{{rp\|32}}

			Evidence from cohort and case-controlled epidemiologic studies demonstrates a positive association between cumulative exposures to tetrachloroethylene and the prevalence of ], ], and ] in adults. Some limited evidence of increased prevalence of kidney, lung, liver, and breast cancers with exposure to tetrachloroethylene has been found in epidemiologic research, but data quality limitations have produced variable results across studies.<ref name=iarc2014/>{{rp\|326}}<ref name=epatox>{{Cite web \|url=https://iris.epa.gov/ChemicalLanding/&substance_nmbr=106 \|title=Tetrachloroethylene (Perchloroethylene) (United States Environmental Protection Agency, Integrated Risk Information System Toxicological Review, 2012) \|website=iris.epa.gov/ \|access-date=23 September 2024}}</ref>{{rp\|§ 4.2.1.3}}<ref name=atsdr>{{Cite web \|url=https://www.atsdr.cdc.gov/toxprofiles/tp18.pdf \|title=Toxicological Profile for Tetrachloroethylene (United States Agency for Toxic Substances and Disease Registry, 2019) \|website=www.atsdr.cdc.gov/ \|access-date=23 September 2024}}</ref>{{rp\|237}}
	The ] has classified tetrachloroethene as a Group 2A ], which means that it is probably carcinogenic to humans.<ref>IARC monograph.
	Vol. 63, p. 159. Last Updated May 20, 1997. Last retrieved June 22, 2007.</ref>

			Several modes of action are hypothesized for the carcinogenicity of tetrachloroethylene in humans, though existing data is insufficient for adequate characterization.<ref name=epatox/>{{rp\|§ 4.2.4, § 4.3.4}} Markers of oxidative metabolism of tetrachloroethylene and increased prevalence of abnormal hepatic sonographs have been observed in dry-cleaners and laundry workers exposed to tetrachloroethylene,<ref name=brodkin>{{cite journal \|last1=Brodkin \|first1=CA \|last2=Daniell \|first2=W \|last3=Checkoway \|first3=H \|last4=Echeverria \|first4=D \|last5=Johnson \|first5=J \|last6=Wang \|first6=K \|last7=Sohaey \|first7=R \|last8=Green \|first8=D \|last9=Redlich \|first9=C \|last10=Gretch \|first10=D \|title=Hepatic ultrasonic changes in workers exposed to perchloroethylene \|journal=] \|date=1995 \|volume=52 \|issue=10 \|pages=679–685 \|doi=10.1136/oem.52.10.679 \|doi-access=free \|pmc=1128334 \|pmid=7489059}}</ref><ref name=gennari>{{cite journal \|last1=Gennari \|first1=P \|last2=Naldi \|first2=M \|last3=Motta \|first3=R \|last4=Nucci \|first4=MC \|last5=Giacomini \|first5=C \|last6=Violante \|first6=FS \|last7=Raffi \|first7=GB \|title=gamma-Glutamyltransferase isoenzyme pattern in workers exposed to tetrachloroethylene \|journal=] \|url=https://onlinelibrary.wiley.com/doi/10.1002/ajim.4700210506 \|date=1992 \|volume=21 \|issue=5 \|pages=661–671 \|doi=10.1002/ajim.4700210506 \|pmid=1351699}}</ref> which suggests a potential for hepatocellular damage through the formation of ] from glutathione conjugates during metabolization.<ref name=iarc2014/>{{rp\|328}}<ref name=atsdr/>{{rp\|10, 189-193}} Although most genotoxicity assays of tetrachloroethylene produced negative findings for genotoxicity and mutagenicity, modest genotoxic effects and mutagenic effects have been identified under certain metabolic activation conditions, and several of tetrachloroethylene's metabolites have been shown to be mutagenic.<ref name=epatox/>{{rp\|§ 4.10.3}}<ref name=atsdr/>{{rp\|172-178}}
	Under a high temperature flame such as those produced by a TIG torch or other welding arcs, ] gas is produced.

	===Testing for exposure===		===Testing for exposure===
			Tetrachloroethylene exposure can be evaluated by a breath test, analogous to breath-alcohol measurements. Also, for acute exposures, tetrachloroethylene in expired air can be measured.<ref>{{Cite web \|date=2021-02-09 \|title=Tetrachloroethylene Toxicity: Section 3.1. Evaluation and Diagnosis \|url=https://www.atsdr.cdc.gov/csem/tetrachloroethylene/section_3_1.html \|access-date=2023-03-02 \|website=] \|language=en-us}}</ref> Tetrachloroethylene can be detected in the breath for weeks following a heavy exposure. Tetrachloroethylene and its metabolite ], can be detected in the blood.
	One method of testing for tetrachloroethene exposure is to measure the amount of the chemical in the breath, much the same way breath-alcohol measurements are used to determine the amount of alcohol in the blood. Because it is stored in the body's fat and slowly released into the bloodstream, tetrachloroethene can be detected in the breath for weeks following a heavy exposure.

			In the European Union, the ] (SCOEL) recommends for tetrachloroethylene an ] (8-hour time-weighted average) of 20 ppm and a short-term exposure limit (15 min) of 40 ppm.<ref>{{cite web\|url= http://ec.europa.eu/social/keyDocuments.jsp?type=0&policyArea=82&subCategory=153&country=0&year=0&advSearchKey=recommendation&mode=advancedSubmit&langId=en\|title=SCOEL recommendations\|date=2011-04-22\|access-date=2011-04-22}}</ref>
	Tetrachloroethene and ] (TCA), a breakdown product of tetrachloroethene, can be detected in the ]. These tests are relatively simple to perform. These tests are not available at most doctors' offices, but can be performed at laboratories with the necessary equipment. Because exposure to other chemicals can produce the same breakdown products in the ] and blood, the tests for breakdown products cannot determine if one has been exposed to tetrachloroethene or the other chemicals.

			==Remediation and degradation==
			In principle, tetrachloroethylene contamination can be remediated by chemical treatment. Chemical treatment involves reducing metals such as iron powder.<ref>{{cite journal \|first1=Timothy J. \|last1=Campbell \|first2=David R. \|last2=Burris \|first3=A. Lynn \|last3=Roberts \|first4=J. Raymond \|last4=Wells \|title=Trichloroethylene and tetrachloroethylene reduction in a metallic iron–water-vapor batch system \|date=October 2009 \|journal=Environmental Toxicology and Chemistry \|volume=16 \|issue=4 \|doi=10.1002/etc.5620160404 \|pages=625–630 \|s2cid=94525849}}</ref>

			] usually entails reductive dechlorination under anaerobic conditions by '']'' spp.<ref>{{cite journal \|doi=10.1016/j.watres.2017.02.001 \|title=Anaerobic biodegradation of (Emerging) organic contaminants in the aquatic environment \|year=2017 \|last1=Ghattas \|first1=Ann-Kathrin \|last2=Fischer \|first2=Ferdinand \|last3=Wick \|first3=Arne \|last4=Ternes \|first4=Thomas A. \|journal=Water Research \|volume=116 \|pages=268–295 \|pmid=28347952 \|doi-access=free \|bibcode=2017WatRe.116..268G \|s2cid=205698959}}</ref> Under aerobic conditions, degradation may occur via co-metabolism by '']'' sp.<ref>{{cite journal \|doi=10.1007/s002530100675 \|last1=Ryoo \|first1=D. \|last2=Shim \|first2=H. \|last3=Arenghi \|first3=F. L. G. \|last4=Barbieri \|first4=P. \|last5=Wood \|first5=T. K. \|year=2001 \|title=Tetrachloroethylene, Trichloroethylene, and Chlorinated Phenols Induce Toluene-o-xylene Monooxoygenase Activity in Pseudomonas stutzeri OX1 \|journal = Appl Microbiol Biotechnol \|volume=56 \|pages=545–549 \|issue = 3–4 \|pmid = 11549035 \| s2cid = 23770815 }}</ref> Products of biological reductive dechlorination include ], ''cis''-], ], ethylene and chloride.

			== Explanatory notes ==
			{{Notelist}}

	==References==		==References==
			{{Reflist}}
	<references/>

	==Further reading==		==Further reading==
	* {{cite web \| publisher = ] \| year = 1997 \| title = Toxicological Profile for Tetrachloroethene \| url = ~~http~~://~~www.atsdr~~.cdc.gov/~~toxprofiles~~/~~tp18~~.~~html~~}}		*{{cite web \| publisher = ] \| year = 1997 \| title = Toxicological Profile for Tetrachloroethene \| url = https://wwwn.cdc.gov/TSP/ToxProfiles/ToxProfiles.aspx?id=265&tid=48}}
			*{{cite journal \| author = Doherty, R.E. \| year = 2000 \| title = A History of the Production and Use of Carbon Tetrachloride, Tetrachloroethylene, Trichloroethylene and 1,1,1-Trichloroethane in the United States: Part 1 - Historical Background; Carbon Tetrachloride and Tetrachloroethylene \| journal = Environmental Forensics \| volume = 1 \| pages = 69–81 \| doi = 10.1006/enfo.2000.0010 \| issue = 2 \| bibcode = 2000EnvFo...1...69D \| s2cid = 97680726 }}

	* {{cite journal \| author = Doherty, R.E. \| year = 2000 \| title = A History of the Production and Use of Carbon Tetrachloride, Tetrachloroethylene, Trichloroethylene and 1,1,1-Trichloroethane in the United States: Part 1 - Historical Background; Carbon Tetrachloride and Tetrachloroethylene \| journal = ] \| volume = 1 \| pages = 69–81 \| doi = 10.1006/enfo.2000.0010 }}

	==External links==		==External links==
	* U.S. ]		* U.S. ]
			* U.S. ]
	* Australian page
			*Australian page
	* by Julian Kesner, New York ''Daily News'', April 20, 2007.
			*, ]

			{{Authority control}}
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			{{Chlorides}}
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Latest revision as of 15:36, 24 November 2024

Chemical compound in very wide use

Tetrachloroethylene

Carbon, C Chlorine, Cl

Names

Preferred IUPAC name Tetrachloroethene

Other names Carbon bichloride; Carbon dichloride (Carboneum Dichloratum); Ethylene tetrachloride; Perchlor; Perchloroethene; Perchloroethylene;

Identifiers

CAS Number

127-18-4

3D model (JSmol)

Interactive image

Abbreviations

PCE; Perc; Per

Beilstein Reference

1304635

ChEBI

CHEBI:17300

ChEMBL

ChEMBL114062

ChemSpider

13837281

ECHA InfoCard

100.004.388

EC Number

204-825-9

Gmelin Reference

101142

KEGG

C06789

PubChem CID

31373

RTECS number

KX3850000

UNII

TJ904HH8SN

UN number

1897

CompTox Dashboard (EPA)

DTXSID2021319

InChI

InChI=1S/C2Cl4/c3-1(4)2(5)6Key: CYTYCFOTNPOANT-UHFFFAOYSA-N
InChI=1/C2Cl4/c3-1(4)2(5)6Key: CYTYCFOTNPOANT-UHFFFAOYAO

SMILES

ClC(Cl)=C(Cl)Cl

Properties

Chemical formula

C₂Cl₄

Molar mass

165.82 g/mol

Appearance

Clear, very refractive, colorless liquid

Odor

Mild, sharp and sweetish

Density

1.622 g/cm

Melting point

−22.0 to −22.7 °C (−7.6 to −8.9 °F; 251.2 to 250.5 K)

Boiling point

121.1 °C (250.0 °F; 394.2 K)

Solubility in water

0.15 g/L (25 °C)

Vapor pressure

14 mmHg (20 °C)

Magnetic susceptibility (χ)

−81.6·10 cm/mol

Refractive index (n_D)

1.505

Viscosity

0.89 cP at 25 °C

Hazards

Occupational safety and health (OHS/OSH):

Main hazards

Inhalation of vapours can cause anaesthesia and respiratory irritation. Causes irritation in contact with skin and eyes with no residual injury.

GHS labelling:

Pictograms

Signal word

Warning

Hazard statements

H351, H411

Precautionary statements

P201, P202, P273, P281, P308+P313, P391, P405, P501

NFPA 704 (fire diamond)

2 0 0

Flash point

Not flammable

Lethal dose or concentration (LD, LC):

LD₅₀ (median dose)

3420 mg/kg (oral, rat)
2629 mg/kg (oral, rat), >10000 mg/kg (dermal, rat)

LC₅₀ (median concentration)

4000 ppm (rat, 4 hr)
5200 ppm (mouse, 4 hr)
4964 ppm (rat, 8 hr)

NIOSH (US health exposure limits):

PEL (Permissible)

TWA 100 ppm
C 200 ppm (for 5 minutes in any 3-hour period), with a maximum peak of 300 ppm

REL (Recommended)

Ca Minimize workplace exposure concentrations.

IDLH (Immediate danger)

Safety data sheet (SDS)

External MSDS

Related compounds

Related analogous organohalides

Tetrafluoroethylene
Tetrabromoethylene
Tetraiodoethylene

Related compounds

Trichloroethylene
Dichloroethylene
1,1,2,2-Tetrachloroethane
Carbon tetrachloride

Supplementary data page

Tetrachloroethylene (data page)

Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa).

N verify (what is ?) Infobox references

Chemical compound

Tetrachloroethylene, also known as perchloroethylene or under the systematic name tetrachloroethene, and abbreviations such as perc (or PERC), and PCE, is a chlorocarbon with the formula Cl₂C=CCl₂. It is a non-flammable, stable, colorless and heavy liquid widely used for dry cleaning of fabrics. It also has its uses as an effective automotive brake cleaner. It has a mild sweet, sharp odor, detectable by most people at a concentration of 50 ppm.

Tetrachloroethylene is regarded as a toxic substance, a human health hazard, and an environmental hazard. In 2020, the United States Environmental Protection Agency stated that "tetrachloroethylene exposure may harm the nervous system, liver, kidneys, and reproductive system, and may be harmful to unborn children", and reported that numerous toxicology agencies regard it as a carcinogen.

History and production

French chemist Henri Victor Regnault first synthesized tetrachloroethylene in 1839 by thermal decomposition of hexachloroethane following Michael Faraday's 1820 synthesis of protochloride of carbon (carbon tetrachloride).

C₂Cl₆ → C₂Cl₄ + Cl₂

Faraday was previously falsely credited for the synthesis of tetrachloroethylene, which in reality, was carbon tetrachloride. While trying to make Faraday's "protochloride of carbon", Regnault found that his compound was different from Faraday's. Victor Regnault stated "According to Faraday, the chloride of carbon boiled around 70 °C (158 °F) to 77 °C (171 °F) degrees Celsius but mine did not begin to boil until 120 °C (248 °F)".

Tetrachloroethylene can be made by passing chloroform vapour through a red-hot tube, the side products include hexachlorobenzene and hexachloroethane, as reported in 1886.

Most tetrachloroethylene is produced by high-temperature chlorinolysis of light hydrocarbons. The method is related to Faraday's method since hexachloroethane is generated and thermally decomposes. Side products include carbon tetrachloride, hydrogen chloride, and hexachlorobutadiene.

Several other methods have been developed. When 1,2-dichloroethane is heated to 400 °C with chlorine, tetrachloroethylene is produced:

ClCH₂CH₂Cl + 3 Cl₂ → Cl₂C=CCl₂ + 4 HCl

This reaction can be catalyzed by a mixture of potassium chloride and aluminium chloride or by activated carbon. Trichloroethylene is a major byproduct, which is separated by distillation.

Worldwide production was about 1 million metric tons (980,000 long tons; 1,100,000 short tons) in 1985.

Although in very small amounts, tetrachloroethylene occurs naturally in volcanoes along with trichloroethylene.

Uses

Tetrachloroethylene is an excellent nonpolar solvent for organic materials. Additionally, it is volatile, highly stable (easily recycled) and nonflammable, and has low toxicity. For these reasons, it has been widely used in dry cleaning worldwide since the 1930s. The chemist Sylvia Stoesser (1901–1991) had suggested tetrachloroethylene to be used in dry cleaning as an alternative to highly flammable dry cleaning solvents such as naphtha.

It is also used to degrease metal parts in the automotive and other metalworking industries, usually as a mixture with other chlorocarbons. It appears in a few consumer products including paint strippers, aerosol preparations and spot removers.

Historical applications

Tetrachloroethylene was once extensively used as an intermediate in the manufacture of HFC-134a and related refrigerants.

In the early 20th century, tetrachloroethene was used for the treatment of hookworm infestation. In 1925, American veterinarian Maurice Crowther Hall (1881–1938), working on anthelmintics, demonstrated the effectiveness of tetrachloroethylene in the treatment of ancylostomiasis caused by hookworm infestation in humans and animals. Before Hall tested tetrachloroethylene on himself, in 1921 he discovered the powerful effect of carbon tetrachloride on intestinal parasites and was nominated for the Nobel Prize in Physiology or Medicine, but a few years later he found tetrachloroethylene to be more effective and safer. Tetrachloroethylene treatment has played a vital role in eradicating hookworms in the United States and abroad. Hall's innovation was considered a breakthrough in medicine. It was given orally as a liquid or in capsules along with magnesium sulfate to get rid of the Necator americanus parasite in humans.

Chemical properties and reactions

Tetrachloroethylene is a derivative of ethylene with all hydrogens replaced by chlorine. 14.49% of the molecular weight of tetrachloroethylene consists of carbon and the remaining 85.5% is chlorine. It is the most stable compound among all chlorinated derivatives of ethane and ethylene. It is resistant to hydrolysis and less corrosive than other chlorinated solvents. It does not tend to polymerise like fluorine analogue tetrafluoroethylene, C₂F₄.

Tetrachloroethylene may react violently with alkali or alkaline earth metals, alkalis (sodium hydroxide and potassium hydroxide), nitric acid, beryllium, barium and aluminium.

Oxidation

Oxidation of tetrachloroethylene by ultraviolet radiation in air produces trichloroacetyl chloride and phosgene:

4 C₂Cl₄ + 3 O₂ → 2 CCl₃COCl + 4 COCl₂

This reaction can be halted by using amines and phenols (usually N-methylpyrrole and N-methylmorpholine) as stabilisers. But the reaction can be done intentionally to produce trichloroacetyl chloride.

Chlorination

Hexachloroethane is formed when tetrachloroethylene reacts with chlorine at 50–80 °C in the presence of a small amount of iron(III) chloride (0.1%) as a catalyst:

C₂Cl₄ + Cl₂ → C₂Cl₆

CFC-113 is produced by the reaction of tetrachloroethylene with chlorine and HF in the presence of antimony pentafluoride:

C₂Cl₄ + 3 HF + Cl₂ → CClF₂CCl₂F + 3 HCl

Nitration

Tetrachlorodinitroethane can be obtained by nitration of tetrachloroethylene with fuming nitric acid (conc. HNO₃ rich in nitrogen oxides) or nitrogen tetroxide:

Cl₂CCCl₂ + N₂O₄ → NO₂Cl₂CCCl₂NO₂

The preparation of this crystalline solid compound from Tetrachloroethylene and nitrogen tetroxide was first described by Hermann Kolbe in 1869.

Thermal decomposition

Tetrachloroethylene begins to thermally decompose at 400 °C, decomposition accelerates around 600 °C, and completely decomposes at 800 °C. Organic decomposition products identified were trichlorobutene, 1,3-dichloro-2-propanone, tetrachlorobutadiene, dichlorocyclopentane, dichloropentene, methyl trichloroacetate, tetrachloroacetone, tetrachloropropene, trichlorocyclopentane, trichloropentene, hexachloroethane, pentachloropropene, hexachloropropene, hexachlorobutadiene.

Health and safety

Tetrachloroethylene is considered to be a toxin. It is identified as a health hazard and environmental hazard. Exposure to tetrachloroethylene, especially over a long term, may harm the nervous system, other organs, and increase the risk of getting cancer. It may also have effects on pregnancy and the fetus.

Reports of human injury are uncommon despite its wide usage in dry cleaning and degreasing. Although limited by its low volatility, tetrachloroethylene has potent anaesthetic effects upon inhalation. The risk depends on whether exposure is over minutes or hours, or over years.

Despite the advantages of tetrachloroethylene, cancer research and government environmental agencies have called for its replacement from widespread commercial use. It is described as a possible neurotoxicant, liver and kidney toxicant and reproductive and developmental toxicant (...) a potential occupational carcinogen. On the other hand, dry cleaning industry emphasizes minimal risk because modern machinery use closed systems to avoid any vapour escape and to optimize recycling.

Metabolism

Tetrachloroethylene's biological half-life is approximately 3 days. About 98% of the inhaled tetrachloroethylene is exhaled unchanged and only about 1–3% is metabolised to tetrachloroethylene oxide which rapidly isomerises into trichloroacetyl chloride. Trichloroacetyl chloride hydrolyses to trichloroacetic acid.

Neurotoxicity

Tetrachloroethylene can harm the nervous system, cause developmental deficits in children, impair vision, and increase the risk of psychiatric diagnoses.

Carcinogenicity

Tetrachloroethylene has been classified as "Group 2A: Probably Carcinogenic" by the International Agency for Research on Cancer (IARC) due to sufficient evidence in experimental animals and limited evidence in humans for non-Hodgkin lymphoma, urinary bladder cancers, and cancers of the esophagus and cervix.

Evidence from cohort and case-controlled epidemiologic studies demonstrates a positive association between cumulative exposures to tetrachloroethylene and the prevalence of bladder cancer, non-Hodgkin lymphoma, and multiple myeloma in adults. Some limited evidence of increased prevalence of kidney, lung, liver, and breast cancers with exposure to tetrachloroethylene has been found in epidemiologic research, but data quality limitations have produced variable results across studies.

Several modes of action are hypothesized for the carcinogenicity of tetrachloroethylene in humans, though existing data is insufficient for adequate characterization. Markers of oxidative metabolism of tetrachloroethylene and increased prevalence of abnormal hepatic sonographs have been observed in dry-cleaners and laundry workers exposed to tetrachloroethylene, which suggests a potential for hepatocellular damage through the formation of reactive intermediates from glutathione conjugates during metabolization. Although most genotoxicity assays of tetrachloroethylene produced negative findings for genotoxicity and mutagenicity, modest genotoxic effects and mutagenic effects have been identified under certain metabolic activation conditions, and several of tetrachloroethylene's metabolites have been shown to be mutagenic.

Testing for exposure

Tetrachloroethylene exposure can be evaluated by a breath test, analogous to breath-alcohol measurements. Also, for acute exposures, tetrachloroethylene in expired air can be measured. Tetrachloroethylene can be detected in the breath for weeks following a heavy exposure. Tetrachloroethylene and its metabolite trichloroacetic acid, can be detected in the blood.

In the European Union, the Scientific Committee on Occupational Exposure Limits (SCOEL) recommends for tetrachloroethylene an occupational exposure limit (8-hour time-weighted average) of 20 ppm and a short-term exposure limit (15 min) of 40 ppm.

Remediation and degradation

In principle, tetrachloroethylene contamination can be remediated by chemical treatment. Chemical treatment involves reducing metals such as iron powder.

Bioremediation usually entails reductive dechlorination under anaerobic conditions by Dehalococcoides spp. Under aerobic conditions, degradation may occur via co-metabolism by Pseudomonas sp. Products of biological reductive dechlorination include trichloroethylene, cis-1,2-dichloroethylene, vinyl chloride, ethylene and chloride.

Explanatory notes

Previously spelt as perchlorethylene

References

^ NIOSH Pocket Guide to Chemical Hazards. "#0599". National Institute for Occupational Safety and Health (NIOSH).
Sigma Aldrich Tetrachloroethylene MSDS
Fischer Scientific Tetrachloroethylene MSDS
"Tetrachloroethylene". Immediately Dangerous to Life or Health Concentrations (IDLH). National Institute for Occupational Safety and Health (NIOSH).
^ "Compound Summary: Tetrachloroethylene". PubChem, US National Library of Medicine. 21 September 2024. Retrieved 24 September 2024.
Browning, Ethel (1953). "Perchloroethylene". Toxicity of Industrial Organic Solvents. Chemical Publishing. pp. 182–185.
^ US Agency for Toxic Substances and Disease Registry (June 2019). "Toxicological Profile for Tetrachloroethylene". US National Library of Medicine. Retrieved 23 September 2024.
^ "Public Health Statement for Tetrachloroethylene (PERC)". US Environmental Protection Agency. 22 June 2020. Retrieved 23 September 2024.
V. Regnault (1839) "Sur les chlorures de carbone CCl et CCl" (On the chlorides of carbon CCl and CCl), Annales de Chimie et de Physique, vol. 70, pages 104–107. Reprinted in German as: V. Regnault (1839). "Ueber die Chlorverbindungen des Kohlenstoffs, C2Cl2 und CCl2". Annalen der Pharmacie. 30 (3): 350–352. doi:10.1002/jlac.18390300310.
W. Ramsay and S. Young, Jahres-Bericht über die Leistungen der chemischen Technologie, 1886, p. 628
^ Rossberg, M.; Lendle, W.; Pfleiderer, G.; Tögel, A.; Dreher, E.-L.; Langer, E.; Rassaerts, H.; Kleinschmidt, P.; Strack, H.; Cook, R.; Beck, U.; Lipper, K.-A.; Torkelson, T.R.; Löser, E.; Beutel, K.K.; Mann, T. "Chlorinated Hydrocarbons". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a06_233.pub2. ISBN 978-3527306732.
Gribble, G. W. (1996). "Naturally occurring organohalogen compounds – A comprehensive survey". Progress in the Chemistry of Organic Natural Products. 68 (10): 1–423. doi:10.1021/np50088a001. PMID 8795309.
Amos, J. Lawrence (1990). "Chlorinated solvents". In Boundy, Ray H.; Amos, J. Lawrence (eds.). A History of the Dow Chemical Physics Lab : the freedom to be creative. New York and Basel: Marcel Dekker, Inc. pp. 71–79.
Young, M.D.; Jeffery, G.M.; Morehouse, W.G.; Freed, J.E.; Johnson, R.S. (1960). "The Comparative Efficacy of Bephenium Hydroxynaphthoate and Tetrachloroethylene against Hookworm and other Parasites of Man". American Journal of Tropical Medicine and Hygiene. 9 (5): 488–491. doi:10.4269/ajtmh.1960.9.488. PMID 13787477. S2CID 19521345.
"Clinical Aspects and Treatment of the More Common Intestinal Parasites of Man (TB-33)". Veterans Administration Technical Bulletin 1946 & 1947. 10: 1–14. 1948.
"Maurice C. Hall". United States National Agricultural Library. Special Collections.
Davison, Forrest Ramon (1940). "Tetrachlorethylene". Synopsis of materia medica, toxicology, and pharmacology for students and practitioners of medicine. p. 181.
Pohanish, Richard P., ed. (2012). "Tetrachloroethylene". Sittig's Handbook of Toxic and Hazardous Chemical Carcinogens (6th ed.). Elsevier. p. 2520. ISBN 978-1-4377-7870-0.
Oshin LA, Промышленные хлорорганические продукты (Promyshlennyye khlororganicheskie produkty). 1978.
Knunyatsya IL. Химическая энциклопедия (Khimicheskaya Entsiklopediya). 1992. ISBN 5-85270-039-8
^ Argo, W. L.; James, E. M.; Donnelly, J. L. (November 1919). "Tetrachlordinitroethane". The Journal of Physical Chemistry. 23 (8): 578–585. doi:10.1021/j150197a004.
Yasuhara, Akio (April 1993). "Thermal decomposition of tetrachloroethylene". Chemosphere. 26 (8): 1507–1512. Bibcode:1993Chmsp..26.1507Y. doi:10.1016/0045-6535(93)90218-T. S2CID 94961581.
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