Butane Explained

Butane or n-butane is an alkane with the formula C4H10. Butane is a highly flammable, colorless, easily liquefied gas that quickly vaporizes at room temperature and pressure. The name butane comes from the root but- (from butyric acid, named after the Greek word for butter) and the suffix -ane. It was discovered in crude petroleum in 1864 by Edmund Ronalds, who was the first to describe its properties,[1] [2] and commercialized by Walter O. Snelling in the early 1910s.

Butane is one of a group of liquefied petroleum gases (LP gases). The others include propane, propylene, butadiene, butylene, isobutylene, and mixtures thereof. Butane burns more cleanly than both gasoline and coal.

History

The first synthesis of butane was accidentally achieved by British chemist Edward Frankland in 1849 from ethyl iodide and zinc, but he had not realized that the ethyl radical dimerized and misidentified the substance.[3]

Edmund Ronalds was the first individual to isolate and describe butane, which he named "hydride of butyl,"[4] based on the naming for the then-known butyric acid, which had been named and described by the French chemist Michel Eugène Chevreul[5] 40 years earlier. Other names arose in the 1860s: "butyl hydride",[6] "hydride of tetryl"[7] and "tetryl hydride",[8] "diethyl" or "ethyl ethylide"[9] and others. August Wilhelm von Hofmann, in his 1866 systemic nomenclature, proposed the name "quartane", and the modern name was introduced to English from German around 1874.[10]

Butane did not have much practical use until the 1910s, when W. Snelling identified butane and propane as components in gasoline and found that, if they were cooled, they could be stored in a volume-reduced liquified state in pressurized containers. In 1911, Snelling's liquified petroleum gas was publicly available, and his process for producing the mixture was patented in 1913.[11] Butane is one of the most produced industrial chemicals in the 21st century with around 80-90 billion lbs (40 million US tons, 36 million metric tons) produced by the United States every year.[12]

Density

The density of butane is highly dependent on temperature and pressure in the reservoir.[13] For example, the density of liquid butane is 571.8±1 kg/m3 (for pressures up to 2MPa and temperature 27±0.2 °C), while the density of liquid butane is 625.5±0.7 kg/m3 (for pressures up to 2MPa and temperature -13±0.2 °C).

Isomers

See main article: C4H10.

Common namenormal butane
unbranched butane
n-butane		isobutane
i-butane
IUPAC namebutanemethylpropane
Molecular
diagram
Skeletal
diagram
Rotation about the central C−C bond produces two different conformations (trans and gauche) for n-butane.[14]

Reactions

When oxygen is plentiful, butane burns to form carbon dioxide and water vapor; when oxygen is limited, carbon (soot) or carbon monoxide may also be formed. Butane is denser than air.

When there is sufficient oxygen:

2 C4H10 + 13 O2 → 8 CO2 + 10 H2OWhen oxygen is limited:

2 C4H10 + 9 O2 → 8 CO + 10 H2O

By weight, butane contains about 49.5MJ/kg or by liquid volume 29.7MJ/L.

The maximum adiabatic flame temperature of butane with air is .

n-Butane is the feedstock for DuPont's catalytic process for the preparation of maleic anhydride:

2 CH3CH2CH2CH3 + 7 O2 → 2 C2H2(CO)2O + 8 H2O

n-Butane, like all hydrocarbons, undergoes free radical chlorination providing both 1-chloro- and 2-chlorobutanes, as well as more highly chlorinated derivatives. The relative rates of the chlorination is partially explained by the differing bond dissociation energies, 425 and 411 kJ/mol for the two types of C-H bonds.

Uses

Normal butane can be used for gasoline blending, as a fuel gas, fragrance extraction solvent, either alone or in a mixture with propane, and as a feedstock for the manufacture of ethylene and butadiene, a key ingredient of synthetic rubber. Isobutane is primarily used by refineries to enhance (increase) the octane number of motor gasoline.[15] [16] [17] [18]

For gasoline blending, n-butane is the main component used to manipulate the Reid vapor pressure (RVP). Since winter fuels require much higher vapor pressure for engines to start, refineries raise the RVP by blending more butane into the fuel.[19] n-Butane has a relatively high research octane number (RON) and motor octane number (MON), which are 93 and 92 respectively.[20]

When blended with propane and other hydrocarbons, the mixture may be referred to commercially as liquefied petroleum gas (LPG). It is used as a petrol component, as a feedstock for the production of base petrochemicals in steam cracking, as fuel for cigarette lighters and as a propellant in aerosol sprays such as deodorants.[21]

Pure forms of butane, especially isobutane, are used as refrigerants and have largely replaced the ozone-layer-depleting halomethanes in refrigerators, freezers, and air conditioning systems. The operating pressure for butane is lower than for the halomethanes such as Freon-12 (R-12), so R-12 systems such as those in automotive air conditioning systems, when converted to pure butane, will function poorly. A mixture of isobutane and propane is used instead to give cooling system performance comparable to use of R-12.[22]

Butane is also used as lighter fuel for common lighters or butane torches and is sold bottled as a fuel for cooking, barbecues and camping stoves. In the 20th century the Braun company of Germany made a cordless hair styling device product that used butane as its heat source to produce steam.[23]

As fuel, it is often mixed with small amounts of mercaptans to give the unburned gas an offensive smell easily detected by the human nose. In this way, butane leaks can easily be identified. While hydrogen sulfide and mercaptans are toxic, they are present in levels so low that suffocation and fire hazard by the butane becomes a concern far before toxicity.[24] [25] Most commercially available butane also contains some contaminant oil, which can be removed by filtration and will otherwise leave a deposit at the point of ignition and may eventually block the uniform flow of gas.[26]

The butane used as a solvent for fragrance extraction does not contain these contaminants[27] and butane gas can cause gas explosions in poorly ventilated areas if leaks go unnoticed and are ignited by spark or flame. Purified butane is used as a solvent in the industrial extraction of cannabis oils.

Effects and health issues

Inhalation of butane can cause euphoria, drowsiness, unconsciousness, asphyxia, cardiac arrhythmia, fluctuations in blood pressure and temporary memory loss, when abused directly from a highly pressurized container, and can result in death from asphyxiation and ventricular fibrillation. It enters the blood supply and within seconds produces intoxication.[28] Butane is the most commonly abused volatile substance in the UK, and was the cause of 52% of solvent related deaths in 2000.[29] By spraying butane directly into the throat, the jet of fluid can cool rapidly to by expansion, causing prolonged laryngospasm.[30] "Sudden sniffer's death" syndrome, first described by Bass in 1970,[31] is the most common single cause of solvent related death, resulting in 55% of known fatal cases.[30]

See also

External links

Notes and References

  1. Book: Watts . H. . Muir . M. M. P. . Morley . H. F. . Watts' Dictionary of Chemistry . Longmans, Green . 4 . 1894 . 385.
  2. Maybery . C. F. . 1896 . On the Composition of the Ohio and Canadian Sulphur Petroleums . Proceedings of the American Academy of Arts and Sciences . 31 . 1–66 . 10.2307/20020618 . 20020618.
  3. 10.1021/om010439f . Zinc Alkyls, Edward Frankland, and the Beginnings of Main-Group Organometallic Chemistry . 2001 . Seyferth . Dietmar . Organometallics . 20 . 14 . 2940–2955 . free.
  4. Web site: Journal of the Chemical Society . 1865 .
  5. Chevreul (1817) "Extrait d'une lettre de M. Chevreul à MM. les Rédacteurs du Journal de Pharmacie" (Extract of a letter from Mr. Chevreul to the editors of the Journal of Pharmacy), Journal de Pharmacie et des sciences accessoires, 3 : 79–81. On p. 81, he named butyric acid: "Ce principe, que j'ai appelé depuis acid butérique, … " (This principle [i.e., constituent], which I have since named "butyric acid", …)
  6. Web site: Petroleum and Its Products: An Accoumt of the Properties, Uses, and Commercial Value Etc., of Petroleum, the Methods Employed in Refining it and the Properties, Uses, Etc., of Its Product . Norman Tate . A. . 1863 .
  7. Web site: A Dictionary of Chemistry . Watts . Henry . 1865 .
  8. Web site: Elements of chemistry pt. 3 1867 . Miller . William Allen . 1867 .
  9. Web site: Elements of Chemistry: Theoretical and Practical: Organic chemistry . Miller . William Allen . 1869 .
  10. Web site: A Manual of the Chemistry of the Carbon Compounds: Or, Organic Chemistry . Schorlemmer . Carl . 1874 .
  11. Web site: The History of Propane . Texas Propane . 2022.
  12. Web site: Chemical Production Data . 2024 .
  13. Zivenko. Oleksiy. LPG Accounting Specificity During ITS Storage and Transportation . 2019. Measuring Equipment and Metrology. en. 80. 3. 21–27. 10.23939/istcmtm2019.03.021. 211776025 . 0368-6418. free.
  14. . 113 . 6 . 1012–9 . 10.1021/jp809639s . Enthalpy Difference between Conformations of Normal Alkanes: Raman Spectroscopy Study of n-Pentane and n-Butane . 2009 . Roman M. Balabin. 19152252. 2009JPCA..113.1012B . Roman Balabin .
  15. https://www.sec.gov/Archives/edgar/data/1166036/000104746912001759/a2207469z10-k.htm MarkWest Energy Partners, L.P. Form 10-K
  16. https://www.sec.gov/Archives/edgar/data/1297067/000119312512089552/d270993d10k.htm Copano Energy, L.L.C. Form 10-K
  17. https://www.sec.gov/Archives/edgar/data/1379661/000138917012000005/form10-k.htm Targa Resources Partners LP Form10-k
  18. https://www.sec.gov/Archives/edgar/data/1179060/000104746912001738/a2207540z10-k.htm Crosstex Energy, L.P. FORM 10-K
  19. Web site: Maurice Stewart, Ken Arnold. Reid Vapour Pressure. live. Science Direct. https://web.archive.org/web/20200613130216/https://www.sciencedirect.com/topics/engineering/reid-vapour-pressure . 13 June 2020 .
  20. Web site: Jechura. John. octane rating. live. Colorado School of Mines. https://web.archive.org/web/20150501041749/http://inside.mines.edu:80/~jjechura/Refining/11_Blending_Optimization.pdf . 1 May 2015 .
  21. http://eprinc.org/?p=300 A Primer on Gasoline Blending
  22. Web site: R600a Product Information . 2023-12-01 . www.agas.com . en-AU.
  23. News: Braun C 100 TS Styling Iron User Manual Type 3589 . Inmar-OIQ, LLC . n.d..
  24. Web site: Gresham . Chip . Hydrogen Sulfide Toxicity: Practice Essentials, Pathophysiology, Etiology . Medscape Reference . 16 November 2019 . 22 March 2021 . registration.
  25. Book: Committee on Acute Exposure Guideline Levels . Committee on Toxicology . Board on Environmental Studies and Toxicology . Division on Earth and Life Studies . National Research Council . 2. Methyl Mercaptan Acute Exposure Guideline Levels . NCBI Bookshelf . 26 September 2013 . National Academies Press (US) .
  26. Web site: BHO Mystery Oil . 2013-08-26 . Skunk Pharm Research . 2019-12-05.
  27. Final Report of the Safety Assessment of Isobutane, Isopentane, n-Butane, and Propane . Journal of the American College of Toxicology . SAGE Publications . 1 . 4 . 1982 . 0730-0913 . 10.3109/10915818209021266 . 127–142. 208503534.
  28. Web site: Neurotoxic Effects from Butane Gas . 19 Dec 2009 . thcfarmer.com . 3 October 2016.
  29. Web site: Trends in death Associated with Abuse of Volatile Substances 1971–2004 . Field-Smith M, Bland JM, Taylor JC . Department of Public Health Sciences. London: St George’s Medical School . etal . dead . https://web.archive.org/web/20070327161634/http://www.sgul.ac.uk/dms/AF54AFD9D207A9A41D353717989DC4E0.pdf . March 27, 2007.
  30. Ramsey J, Anderson HR, Bloor K . etal . An introduction to the practice, prevalence and chemical toxicology of volatile substance abuse . Hum Toxicol . 1989 . 8 . 261–269 . 10.1177/096032718900800403 . 2777265 . 4. 19617950.
  31. Bass M . Sudden sniffing death . JAMA . 1970 . 212 . 12 . 2075–2079 . 10.1001/jama.1970.03170250031004 . 5467774.

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