|Preferred IUPAC name
3D model (JSmol)
CompTox Dashboard (EPA)
|Density||0.6606 g mL-1|
|Melting point||-96 to -94 °C; -141 to -137 °F; 177 to 179 K|
|Boiling point||68.5 to 69.1 °C; 155.2 to 156.3 °F; 341.6 to 342.2 K|
|9.5 mg L-1|
|Vapor pressure||17.60 kPa (at 20.0 °C)|
|7.6 nmol Pa-1 kg-1|
|UV-vis (?max)||200 nm|
Refractive index (nD)
Heat capacity (C)
|265.2 J K-1 mol-1|
|296.06 J K-1 mol-1|
Std enthalpy of
|-199.4--198.0 kJ mol-1|
Std enthalpy of
|-4180--4140 kJ mol-1|
|Main hazards||Reproductive toxicity - After aspiration, pulmonary oedema, pneumonitis|
|Safety data sheet||See: data page|
|GHS Signal word||Danger|
|H225, H302, H305, H315, H336, H361fd, H373, H411|
|P201, P202, P210, P233, P240, P241, P242, P243, P260, P264, P271, P273, P280, P281, P301+330+331, P310, P302+352, P303+361+353, P304+340, P312, P308+313, P314, P332+313, P363, P370+378|
|NFPA 704 (fire diamond)|
|Flash point||-26.0 °C (-14.8 °F; 247.2 K)|
|234.0 °C (453.2 °F; 507.1 K)|
|Lethal dose or concentration (LD, LC):|
LD50 (median dose)
|25 g kg-1 (oral, rat)|
28710 mg/kg (rat, oral)
LDLo (lowest published)
|56137 mg/kg (rat, oral)|
|NIOSH (US health exposure limits):|
|TWA 500 ppm (1800 mg/m3)|
|TWA 50 ppm (180 mg/m3)|
IDLH (Immediate danger)
|Supplementary data page|
|Refractive index (n),|
Dielectric constant (?r), etc.
|UV, IR, NMR, MS|
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
|what is ?)(|
Hexane is a significant constituent of gasoline. It is a colorless liquid, odorless when pure, and with boiling points approximately 69 °C (156 °F). It is widely used as a cheap, relatively safe, largely unreactive, and easily evaporated non-polar solvent.
The term hexanes refers to a mixture, composed largely (>60%) of hexane, with varying amounts of the isomeric compounds 2-methylpentane and 3-methylpentane, and, possibly, smaller amounts of nonisomeric C5, C6, and C7 (cyclo)alkanes. Hexanes is cheaper than hexane and is often used in large scale operations not requiring a single isomer (e.g., as cleaning solvent or for chromatography).
|Common name||IUPAC name||Text formula||Skeletal formula|
In industry, hexanes are used in the formulation of glues for shoes, leather products, and roofing. They are also used to extract cooking oils (such as canola oil or soy oil) from seeds, for cleansing and degreasing a variety of items, and in textile manufacturing. They are commonly used in food based soybean oil extraction in the United States, and are potentially present as contaminants in all soy food products in which the technique is used; the lack of regulation by the FDA of this contaminant is a matter of some controversy.
A typical laboratory use of hexanes is to extract oil and grease contaminants from water and soil for analysis. Since hexane cannot be easily deprotonated, it is used in the laboratory for reactions that involve very strong bases, such as the preparation of organolithiums. For example, butyllithiums are typically supplied as a hexane solution.
Hexanes are commonly used in chromatography as a non-polar solvent. Higher alkanes present as impurities in hexanes have similar retention times as the solvent, meaning that fractions containing hexane will also contain these impurities. In preparative chromatography, concentration of a large volume of hexanes can result in a sample that is appreciably contaminated by alkanes. This may result in a solid compound being obtained as an oil and the alkanes may interfere with analysis.
Hexanes are chiefly obtained by refining crude oil. The exact composition of the fraction depends largely on the source of the oil (crude or reformed) and the constraints of the refining. The industrial product (usually around 50% by weight of the straight-chain isomer) is the fraction boiling at 65-70 °C (149-158 °F).
Although hexanes are useful for laboratories as an extraction solvent, they are typically difficult to purchase outside of a professional laboratory. Hexanes can, however, be isolated from many sources including gasoline, camping fuel, and many hydrocarbon based solvents. The typical process for isolating hexanes from these include fractional distillation of the hydrocarbon source, with a fraction collected around 65-70 °C (149-158 °F). This is then followed by oxidation of side products under an acidic environment such as alcohols, alkenes, and toluene, and re-distillation of the solution to isolate a mixture of n-hexane and the various isomers. The final product typically contains a roughly 50 percent volume of the straight chain isomer.
All alkanes are colorless. The boiling points of the various hexanes are somewhat similar and, as for other alkanes, are generally lower for the more branched forms. The melting points are quite different and the trend is not apparent.
|Isomer||M.P. (°C)||M.P. (°F)||B.P. (°C)||B.P. (°F)|
Hexane has considerable vapor pressure at room temperature:
|Temperature (°C)||Temperature (°F)||Vapor pressure (mmHg)||Vapor pressure (kPa)|
Like most alkanes, hexane characteristically exhibits low reactivity and are suitable solvents for reactive compounds. Commercial samples of n-hexane however often contains methylcyclopentane, which features tertiary C-H bonds, which are incompatible with some radical reactions.
Inhalation of n-hexane at 5000 ppm for 10 minutes produces marked vertigo; 2500-1000 ppm for 12 hours produces drowsiness, fatigue, loss of appetite, and paresthesia in the distal extremities; 2500-5000 ppm produces muscle weakness, cold pulsation in the extremities, blurred vision, headache and anorexia. Chronic occupational exposure to elevated levels of n-hexane has been demonstrated to be associated with peripheral neuropathy in auto mechanics in the US, and neurotoxicity in workers in printing presses, and shoe and furniture factories in Asia, Europe, and North America.
The US National Institute for Occupational Safety and Health (NIOSH) has set a recommended exposure limit (REL) for hexane isomers (not n-hexane) of 100 ppm (350 mg/m3 (0.15 gr/cu ft)) over an 8-hour workday. However, for n-hexane, the current NIOSH REL is 50 ppm (180 mg/m3 (0.079 gr/cu ft)) over an 8-hour workday. This limit was proposed as a permissible exposure limit (PEL) by the Occupational Safety and Health Administration in 1989; however, this PEL was overruled in US courts in 1992. The current n-hexane PEL in the US is 500 ppm (1,800 mg/m3 (0.79 gr/cu ft)).
Hexane and other volatile hydrocarbons (petroleum ether) present an aspiration risk. n-Hexane is sometimes used as a denaturant for alcohol, and as a cleaning agent in the textile, furniture, and leather industries. It is slowly being replaced with other solvents.
Like gasoline, hexane is highly volatile and is an explosion risk. Ignition of hexane vapors which had been illegally discharged in the sewers of Louisville (Kentucky) from a soybean processing plant owned by Ralston-Purina caused a series of explosions which destroyed more over 21 km of sewer lines and streets in that city.
Occupational hexane poisoning has occurred with Japanese sandal workers, Italian shoe workers, Taiwan press proofing workers, and others. Analysis of Taiwanese workers has shown occupational exposure to substances including n-hexane. In 2010-2011, Chinese workers manufacturing iPhones were reported to have suffered hexane poisoning.
Hexane was identified as being the cause of the Louisville sewer explosions on 13 February 1981, that destroyed more than 13 miles (21 km) of sewer lines and streets in the center of Louisville in Kentucky, United States
n-Hexane is biotransformed to 2-hexanol and further to 2,5-hexanediol in the body. The conversion is catalyzed by the enzyme cytochrome P450 utilizing oxygen from air. 2,5-Hexanediol may be further oxidized to 2,5-hexanedione, which is neurotoxic and produces a polyneuropathy. In view of this behavior, replacement of n-hexane as a solvent has been discussed. n-Heptane is a possible alternative.