Polytetrafluoroethylene

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Polytetrafluoroethylene
IUPAC name
Systematic name Poly(tetrafluoroethylene)
Other names Teflon, Syncolon, Polytetrafluoroethene
Identifiers
Abbreviations PTFE
CAS number [9002-84-0]
Properties
Molecular formula CnF2n+2
Density 2200 kg/m3
Melting point

327 °C
Supplementary data page
Structure and
properties		 n, εr, etc.
Thermodynamic
data		 Phase behaviour
Solid, liquid, gas
Spectral data UV, IR, NMR, MS
Except where noted otherwise, data are given for
materials in their standard state
(at 25 °C, 100 kPa)
Infobox references

In chemistry, polytetrafluoroethylene (PTFE) is a synthetic fluoropolymer of tetrafluoroethylene which finds numerous applications. PTFE is most well known by the DuPont brand name Teflon.

PTFE is a fluorocarbon solid, as it is a high molecular weight compound consisting wholly of carbon and fluorine. Neither water and water-containing substances nor oil and oil-containing substances are wet by PTFE, as fluorocarbons demonstrate mitigated London dispersion forces due to the high electronegativity of fluorine.

PTFE is used as a non-stick coating for pans and other cookware. It is very non-reactive, partly because of the strength of carbon–fluorine bonds, and so it is often used in containers and pipework for reactive and corrosive chemicals. Where used as a lubricant, PTFE reduces friction, wear and energy consumption of machinery.

Contents

[edit] History

PTFE was accidentally invented by Roy Plunkett of Kinetic Chemicals in 1938. While Plunkett was attempting to make a new CFC refrigerant, the perfluorethylene polymerized in its pressurized storage container, with the iron from the inside of the container acting as a catalyst. Kinetic Chemicals patented it in 1941[1] and registered the Teflon trademark in 1945.[2][3]

By 1950, DuPont had acquired interest in Kinetic Chemicals and was producing over a million pounds (450 tons) of Teflon per year in Parkersburg, West Virginia. In 1954, French engineer Marc Grégoire created the first pan coated with Teflon non-stick resin under the brandname of Tefal after his wife urged him to try the material he had been using on fishing tackle on her cooking pans.[4] In the United States, Kansas City, Missouri resident Marion A. Trozzolo, who had been using the substance on scientific utensils, marketed the first frying pan, "The Happy Pan," in 1961.[5]

An early advanced use was in the Manhattan Project as a material to coat valves and seals in the pipes holding highly reactive uranium hexafluoride in the vast uranium enrichment plant at Oak Ridge, Tennessee, when it was known as K-25.

[edit] Properties

PTFE is often used to coat non-stick frying pans as it is hydrophobic and possesses fairly high heat resistance.

PTFE is a white solid at room temperature, with a density of about 2.2 g/cm³. According to DuPont its melting point is 327 °C (620.6 °F), but its properties degrade above 260 °C (500 °F).[6] PTFE gains its properties from the aggregate effect of carbon-fluorine bonds, as do all fluorocarbons.

The coefficient of friction of plastics is usually measured against polished steel.[7] PTFE's coefficient of friction is 0.1 or less[6], which is the second lowest of any known solid material (diamond-like carbon being the first). PTFE's resistance to van der Waals forces means that it is the only known surface to which a gecko cannot stick[8], though it can still use the hairs on its feet like a spider to climb.

PTFE has excellent dielectric properties. This is especially true at high radio frequencies, making it suitable for use as an insulator in cables and connector assemblies and as a material for printed circuit boards used at microwave frequencies. Combined with its high melting temperature, this makes it the material of choice as a high-performance substitute for the weaker and lower melting point polyethylene that is commonly used in low-cost applications. Its extremely high bulk resistivity makes it an ideal material for fabricating long life electrets, useful devices that are the electrostatic analogues of magnets.

Because of its chemical inertness, PTFE cannot be cross-linked like an elastomer. Therefore it has no "memory," and is subject to creep, also known as "cold flow" and "compression set". A little bit of creep allows PTFE seals to conform to mating surfaces better than most other plastic seals. Too much creep, however, and the seal can be compromised. Compounding fillers control unwanted creep and improve wear, friction, and other properties. Sometimes metal springs apply continuous force to PTFE seals to give good contact, while permitting some creep.

Due to its low friction, it is used for applications where sliding action of parts is needed: bearings, bushings, gears, slide plates, etc. In these applications it performs significantly better than nylon and acetal; it is comparable to ultra high-molecular weight polyethylene (UHMWPE), although UHMWPE is more resistant to wear than Teflon. For these applications, versions of teflon with mineral oil or molybdenum disulfide embedded as additional lubricants in its matrix are being manufactured.

Gore-Tex is a material incorporating fluoropolymer membrane with micropores. The roof of the Hubert H. Humphrey Metrodome in Minneapolis is one of the largest applications of Teflon PTFE coatings on Earth, using 20 acres (81,000 m2) of the material in a double-layered, white dome, made with PTFE-coated fiberglass, that gives the stadium its distinctive appearance. The Millennium Dome in London is also substantially made of PTFE.

Powdered PTFE is used in pyrotechnic compositions as oxidizer together with powdered metals such as aluminium and magnesium. Upon ignition these mixtures form carbonaceous soot and the corresponding metal fluoride and release large amounts of heat. Hence they are used as infrared decoy flares and igniters for solid-fuel rocket propellants.[9]

PTFE is also used in body piercings, such as a sub-clavicle piercing, due to its flexibility and bio-compatibility.

In optical radiometry, sheets made from PTFE are used as measuring heads in spectroradiometers and broadband radiometers (e.g. illuminance meters and UV radiometers) due to its capability to diffuse a transmitting light nearly perfectly. Moreover, optical properties of PTFE stay constant over a wide range of wavelengths, from UV up to near infrared. In this region, the relation of its regular transmittance to diffuse transmittance is negligibly small so light transmitted through a diffuser (PTFE sheet) radiates like Lambert's cosine law. Thus, PTFE enables cosinusoidal angular response for a detector measuring the power of optical radiation at a surface, e.g., in solar irradiance measurements.

PTFE is also used to coat certain types of hardened, armor-piercing bullet, so as to reduce the amount of wear on the firearm's rifling. These are often referred to as "cop-killer" bullets by virtue of PTFE's supposed ability to ease a bullet's passage through body armor. However, this is simply an urban myth as PTFE has no effect in the bullet's ability to penetrate soft body armor, only on the ability to prevent damage to the weapon from firing very hard ammunition.

PTFE's low frictional properties have also been utilized as computer mice feet such as the Logitech G5, Logitech G7 and Logitech G9 computer mice series from Logitech or most Razer gaming mice (e.g. the Deathadder, Lachesis). The low friction provided by PTFE allows the mice to be moved and glide across surfaces smoothly and with less effort.

PTFE's high corrosion resistance makes it ideal for laboratory environments as containers, magnetic stirrers and tubing for highly corrosive chemicals such as hydrofluoric acid, which will dissolve glass containers.

PTFE can be used as a thread seal tape in plumbing applications.

PTFE grafts can be used to bypass stenotic arteries in peripheral vascular disease, if a suitable autologous vein graft is not available.

PTFE can be used to prevent insects climbing up surfaces painted with the material. PTFE is so slippery that insects cannot get a grip and tend to fall off. For example PTFE is used to prevent ants climbing out of formicaria.

[edit] Safety

The pyrolysis of PTFE is detectable at 200 °C (392 °F), and it evolves several fluorocarbon gases and a sublimate. Animal studies indicate that it is highly unlikely that these products would be generated in amounts significant to health at temperatures below 250 °C (482 °F).[10] While PTFE is stable and non-toxic, it begins to deteriorate after the temperature of cookware reaches about 260 °C (500 °F), and decompose above 350 °C (660 °F).[11] These degradation products can be lethal to birds, and can cause flu-like symptoms in humans.[11]

Cooking fats, oils, and butter will begin to scorch and smoke at about 200 °C (392 °F), and meat is usually fried between 200–230 °C (400–450 °F), but empty cookware can exceed this temperature if left unattended on a hot burner.

A 1959 study (conducted before the U.S. Food and Drug Administration approved the material for use in food processing equipment) showed that the toxicity of fumes given off by the coated pan on dry heating was less than that of fumes given off by ordinary cooking oils.[12]

[edit] Carcinogens in production

The United States Environmental Protection Agency's scientific advisory board found in 2005 that perfluorooctanoic acid (PFOA), a chemical compound used to make Teflon, is a "likely carcinogen." This finding was part of a draft report that has yet to be made final.[13] DuPont settled for $300 million in a 2004 lawsuit filed by residents near its manufacturing plant in Ohio and West Virginia based on groundwater pollution from this chemical. Currently this chemical is not regulated by the EPA.

In January 2006, DuPont, the only company that manufactures PFOA in the US, agreed to eliminate releases of the chemical from its manufacturing plants by 2015,[14] but did not commit to completely phasing out its use of the chemical. This agreement is said to apply to not only PTFE used in cookware but also other products such as food packaging, clothing, and carpeting. DuPont also stated that it cannot produce PTFE without the use of the chemical PFOA, although it is looking for a substitute.

PFOA is used only during the manufacture of the product—only a trace amount of PFOA remains after the curing process. DuPont maintains that there should be no measurable amount of PFOA on a finished pan, provided that it has been properly cured.[15] A 2005 U.S. Food and Drug Administration (FDA) study detected PFOA in finished PTFE products including PTFE/Teflon cookware.[16] A February 2007 New York State Department of Health study detected PFOA in the gas phase coming from new nonstick cookware and microwave popcorn bags;[17] this research was funded by a 2005–2006 $17,700 grant from the Consumers Union.[18]

As of August 2008, the EPA's position was that it "has no information that routine use of household or other products using fluoropolymers, such as non-stick cookware or all weather clothing, poses a concern."[19]

[edit] Similar polymers

Teflon is also used as the trade name for a polymer with similar properties, perfluoroalkoxy polymer resin (PFA).

Other polymers with similar composition are also known by the Teflon name:

They retain the useful properties of PTFE of low friction and non-reactivity, but are more easily formable. FEP is softer than PTFE and melts at 260 °C; it is highly transparent and resistant to sunlight.[20]

[edit] See also

[edit] Footnotes

  1. ^ Plunkett, Roy J, "Tetrafluoroethylene polymers", US 2230654, issued 1941-02-04.
  2. ^ History Timeline 1930: The Fluorocarbon Boom, http://www.refrigerants.dupont.com/Suva/en_US/about/history/history_1930.html, retrieved on 2009-06-10 .
  3. ^ Roy Plunkett : 1938, http://www2.dupont.com/Heritage/en_US/1938_dupont/1938_indepth.html, retrieved on 2009-06-10 .
  4. ^ Teflon History - Retrieved 2009-01-25.
  5. ^ TEFLON MAKER: OUT OF FRYING PAN INTO FAME - New York Times - 21 December 1986
  6. ^ a b Fluoropolymer Comparison - Typical Properties www2.dupont.com. Retrieved 10 September 2006.
  7. ^ Coefficient of Friction (COF) Testing of Plastics MatWeb Material Property Data Retrieved 1 January 2007.
  8. ^ Research
  9. ^ E.-C. Koch "Metal-Fluorocarbon Pyrolants:III. Development and Application of Magnesium/Teflon/Viton" Propellants Explosives Pyrotechnics (2002),27(5),pp. 262–266.
  10. ^ Zapp JA, Limperos G, Brinker KC (1955-04-26). "Toxicity of pyrolysis products of 'Teflon' tetrafluoroethylene resin". Proceedings of the American Industrial Hygiene Association Annual Meeting. 
  11. ^ a b DuPont, Key Questions About Teflon, accessed on 3 December 2007.
  12. ^ Dale Blumenthal. "Is That Newfangled Cookware Safe?". Food and Drug Administration. http://www.fda.gov/bbs/topics/CONSUMER/CON00036.html. Retrieved on 2006-05-20. 
  13. ^ "Perfluorooctanoic acid human health risk assessment review panel". Environmental Protection Agency. http://www.epa.gov/sab/panels/pfoa_rev_panel.htm. Retrieved on 2005-05-20. 
  14. ^ Juliet Eilperin (2006-01-26). "Harmful PTFE chemical to be eliminated by 2015". Washington Post. http://www.washingtonpost.com/wp-dyn/content/article/2006/01/25/AR2006012502041.html. Retrieved on 2006-09-10. 
  15. ^ "About Teflon". DuPont. http://www2.dupont.com/PFOA/en_US/about_teflon/. Retrieved on 2006-05-20. 
  16. ^ Begley TH, White K, Honigfort P, Twaroski ML, Neches R, Walker RA.: "Perfluorochemicals: potential sources of and migration from food packaging" Food Addit Contam. 2005 Oct;22(10):1023-31.
  17. ^ Sinclair E, Kim SK, Akinleye HB, Kannan K.: "Quantitation of gas-phase perfluoroalkyl surfactants and fluorotelomer alcohols released from nonstick cookware and microwave popcorn bags" Environ Sci Technol. 2007 15 Feb;41(4):1180-5.
  18. ^ ISI Web of Knowledge "ISI Highly Cited Researchers - A0213-2006-J" Thomson ISI. Last updated 26 September 2006, (Accessed 25 October 2008).
  19. ^ "Failure to Report Chemical Risks Can Result in Major Fines, EPA Office of Civil Enforcement". Environmental Protection Agency. 2008-08. http://www.epa.gov/compliance/resources/newsletters/civil/enfalert/8e-tsca-0807.pdf. Retrieved on 2009-01-19. 
  20. ^ FEP Detailed Properties Parker-TexLoc, 13 April 2006. Retrieved 10 September 2006.

[edit] References

  • Ellis, D.A.; Mabury, S.A.; Martin, J.W.; Muir, D.C.G. (2001). "Thermolysis of fluoropolymers as a potential source of halogenated organic acids in the environment". Nature 412 (6844): 321–324. doi:10.1038/35085548. 

[edit] External links

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