Tetra-ethyl lead
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| Tetra-ethyl lead | |
|---|---|
| Image:Tera-ethyl-lead-chemical.png | |
| General | |
| Systematic name | ? |
| Other names | TEL </br> lead tetraethyl |
| Molecular formula | C8H20Pb |
| SMILES | ? |
| Molar mass | 323.44 g/mol |
| Appearance | colorless, viscous liquid |
| CAS number | [78-00-2] |
| Properties | |
| Density and phase | 1.653 g/mL at 25 °C |
| Solubility in water | insoluble |
| Other solvents | solubie in benzene, hexane |
| Melting point | −136 °C |
| Boiling point | 84-85 °C15 mm Hg |
| refractive index | 1.519 |
| Basicity (pKb) | ? |
| Viscosity | ? cP at ? °C |
| Structure | |
| Molecular shape | tetrahedral |
| Crystal structure | ? |
| Dipole moment | 0 D |
| Hazards | |
| MSDS | External MSDS |
| Main hazards | ? |
| NFPA 704 | |
| Flash point | 163 °F |
| R/S statement | R:61-26/27/28-33-50/53-62 S: 53-45-60-61 |
| RTECS number | TP4550000 |
| Supplementary data page | |
| Structure and properties | n, εr, etc. |
| Thermodynamic data | Phase behaviour Solid, liquid, gas |
| Spectral data | UV, IR, NMR, MS |
| Related compounds | |
| Other anions | ? |
| Other cations | ? |
| Related ? | ? |
| Related compounds | ? |
| Except where noted otherwise, data are given for materials in their standard state (at 25 °C, 100 kPa) Infobox disclaimer and references | |
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Tetra-ethyl lead (also known as TEL, lead tetraethyl and tetraethyllead) is a toxic organometallic chemical compound, with formula (CH3CH2)4Pb, which was once used as a gasoline (petrol) additive. It is still in use today as an additive in aviation fuel.
Contents |
Synthesis and properties
TEL is produced by reacting ethyl chloride with a sodium-lead alloy.
- Pb + 4 Na + 4 CH3CH2Cl → (CH3CH2)4Pb + 4 NaCl
The product, TEL, is a viscous colorless liquid. Because TEL is charge neutral (vs. a salt) and contains an exterior of alkyl groups, it is highly lipophilic and soluble in petrol.
The most noteworthy feature of TEL is the weakness of its four C-Pb bonds. At the temperatures found in internal combustion engines (CH3CH2)4Pb decomposes, first into (CH3CH2)3Pb and an ethyl radicals. These radicals help to propagating the combustion, which itself is a radical reaction. When (CH3CH2)4Pb burns, it produces, not only carbon dioxide and water, but also lead:
- (CH3CH2)4Pb + 13 O2 → 8 CO2 + 10 H2O + Pb
This lead can oxidize further to give species such as lead oxide)
- Pb + 0.5 O2 → PbO
The Pb and PbO would quickly accumulate and destroy an engine. For this reason, lead scavengers such as ethylene dibromide and 1,2-dichloroethane are used in conjunction with TEL - these agents form volatile lead(II) bromide and lead(II) chloride, respectively, which are exhausted from the engine (and into the air).
Uses of TEL as an antiknock agent
TEL was once used extensively as an additive in gasoline (petrol) for its ability to increase the fuel's octane rating (that is, to prevent its premature detonation ("knocking") in the engine) thus allowing the use of higher compression ratios for greater efficiency and power. In addition some of the lead deposited on the valve seats and helped protect them against wear.
The use of TEL in gasoline was mostly dominant in the US while in Europe alcohol was used instead. However the dominance of the US oil companies eventually led to a switch to leaded fuel. In most Western countries this additive went out of use in the late 20th century, chiefly because of the realization that most of its lead—which is toxic to humans and other organisms—ended up in the exhaust fumes and became a major health and environmental problem. The need for that additive was also lessened by the introduction of harder metals for valves and valve-seats, a general reduction in engine compression ratios and the introduction of other anti-knocking additives. The deployment of the catalytic converter (which TEL contaminated and rendered ineffective) further reduced TEL use. TEL remains an ingredient of aviation gasoline and is also still available from a limited number of outlets as a fuel additive, mostly for owners of classic and vintage cars and motorcycles. A more environmental friendly additive is composed of contains 10 ppm potassium (sometimes sodium), solvents and 75% diesel, and is added to unleaded fuel to boost the octane rating by 2-3 points.
In earlier times many vehicles produced before TEL's phase-out required modification to a greater or lesser extent to run successfully on unleaded gasoline. The installation of new hardened valve seats can be done by a competent automotive machine shop. A major engine rebuild, generally by the use of dished pistons, is required to reduce the compression ratio of some older high-performance engines (which required 100-octane fuel) to a ratio that is compatible with currently available gasoline ratings and this reform necessarily entails a decrease in engine power. However by the 21st century additives were available to allow continued use of even these sensitive engines, more or less to their normal function. TEL is still in use today as a component of 100 octane aviation fuel, as a suitable replacement for it in the aviation industry has not yet been found.
History
TEL was found to be an effective anti-knocking agent by Thomas Midgley in 1921, working under Charles Kettering at General Motors Research. Due to its extreme toxicity, many early researchers of TEL became ill (including Midgley himself), and dozens died [1]. In 1924, DuPont and General Motors created the Ethyl Gasoline Corporation to produce and market TEL. In the US in 1972, the EPA launched an initiative to phase out leaded gasoline, which caused Ethyl Corp. to sue the EPA. The EPA won, so in 1976 the phase out began and was completed by 1986. A 1994 study indicated that the concentration of lead in blood dropped 78% from 1978 to 1991 [2].
Leaded gasoline phased out in the European Union on the 1st January 2000, & was only recently phased out in China (around 2001).
Even though leaded gasoline is largely gone in North America, it has left high concentrations of lead in the dirt adjacent to all roads that were constructed prior to its phaseout. Child development specialists often advise parents to not let their children play in such dirt, especially because some children like to eat dirt (see pica).
Alternative antiknock agents
Since the main problem with TEL is its lead content, many alternative additives that contain less poisonous metals have been examined. Methylcyclopentadienyl Manganese Tricarbonyl (MMT or methylcymantrene) is used as an antiknock agent in Canada, but it is apparently banned in the US. Ferrocene has also been reported as an effective antiknock agent.
Reference
"Leaded Gasoline, Safe Refrigeration, and Thomas Midgley, Jr." Chapter 6 in S. Bertsch McGrayne "Prometheans in the Lab" McGraw-Hill: New York, 2002. ISBN: 0071407952
See also
External links
- Case Studies in Environmental Medicine (CSEM): Lead Toxicity
- ToxFAQs™: Lead
- Bartleby Entry on Tetra-ethyl Lead
- National Pollutant Inventory - Lead and Lead Compounds Fact Sheet
- Charles F. Kettering and the 1921 Discovery of Tetraethyl Lead
- Detailed Post from USENET on the History Tetra-ethyl lead's Safety
- TetraBOOST - Engine additive for vintage and classic cars
- True unleaded alternative for 100LL needed for general aviationde:Tetraethylblei
fr:Tétraéthylplomb ja:四エチル鉛 nl:Tetraethyllood pl:Tetraetyloołów ru:Тетраэтилсвинец tr:Kurşun tetra-etil zh:四乙基鉛