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Physical properties

in hydrocarbon in Aliphatic hydrocarbons

Written by Francis A. Carey

Fact-checked by The Editors of Encyclopaedia Britannica

Last Updated: Jun 4, 2025 • Article History

Key People:: Pierre-Eugène-Marcellin Berthelot; George A. Olah; Charles-Adolphe Wurtz

Related Topics:: cycloalkane; cyclo-compound; straight-chain hydrocarbon; arene; polyene

On the Web:: Chemistry LibreTexts - Hydrocarbons (June 04, 2025)

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The physical properties of alkenes and alkynes are generally similar to those of alkanes or cycloalkanes with equal numbers of carbon atoms. Alkynes have higher boiling points than alkanes or alkenes, because the electric field of an alkyne, with its increased number of weakly held π electrons, is more easily distorted, producing stronger attractive forces between molecules.

Boiling points of alkenes and alkynes
name	formula	boiling point (°C)
ethylene	CH₂=CH₂	−103.7
acetylene	HC≡CH	−84.0
propene	CH₂=CHCH₃	−47.6
propyne	HC≡CCH₃	−23.2
1-butene	CH₂=CHCH₂CH₃	−6.1
cis-2-butene	cis-CH₃CH=CHCH₃	+3.7
trans-2-butene	trans-CH₃CH=CHCH₃	+0.9
2-methylpropene	CH₂=C(CH₃)₂	−6.6
1-butyne	HC≡CCH₂CH₃	+8.1
2-butyne	CH₃C≡CCH₃	+27.0
1-pentene	CH₂=CHCH₂CH₂CH₃	+30.2
1-pentyne	HC≡CCH₂CH₂CH₃	+40.2

Chemical properties

Alkenes react with a much richer variety of compounds than alkanes. The characteristic reaction of alkanes is substitution; that of alkenes and alkynes is addition to the double or triple bond. Hydrogenation is the addition of molecular hydrogen (H₂) to a multiple bond, which converts alkenes to alkanes. The reaction occurs at a convenient rate only in the presence of certain finely divided metal catalysts, such as nickel (Ni), platinum (Pt), palladium (Pd), or rhodium (Rh).

Hydrocarbon. Hydrogenation reaction of an alkene in the presence of certain finely divided metal catalysts such as nickel, platinum, palladium, or rhodium.

Hydrogenation is used to prepare alkanes and cycloalkanes and also to change the physical properties of highly unsaturated vegetable oils to increase their shelf life. In such processes the liquid oils are converted to fats of a more solid consistency. Butter substitutes such as margarine are prepared by partial hydrogenation of soybean oil.

Significant progress has been made in developing catalysts for enantioselective hydrogenation. An enantioselective hydrogenation is a hydrogenation in which one enantiomer of a chiral molecule (a molecule that can exist in two structural forms, or enantiomers) is formed in greater amounts than the other. This normally involves converting one of the carbons of the double bond to a stereogenic centre.

Typical catalysts for enantioselective hydrogenation are based on enantiomerically homogeneous ligands bonded to rhodium. Enantioselectivities exceeding 90 percent of a single enantiomer are commonplace in enantioselective hydrogenations, a major application of which is in the synthesis of enantiomerically pure drugs.

The halogens bromine and chlorine add to alkenes to yield dihaloalkanes. Addition is rapid even at room temperature and requires no catalyst. The most important application of this reaction is the addition of chlorine to ethylene to give 1,2-dichloroethane, from which vinyl chloride is prepared.

Hydrocarbon. The addition of chlorine to ethylene results in 1,2-dichloroethane, from which vinyl chloride is prepared.

Compounds of the type HX, where X is a halogen or other electronegative group, also add to alkenes; the hydrogen atom of HX becomes bonded to one of the carbon atoms of the C=C unit, and the X atom becomes bonded to the other.

Hydrocarbon. 2,3-dimethyl-2-butene + hydrogen chloride yields 2-chloro-2,3-dimethylbutane.

If HX is a strong acid, such as hydrochloric (HCl) or hydrobromic (HBr) acid, the reaction occurs rapidly; otherwise, an acid catalyst is required. One source of industrial ethanol, for example, is the reaction of ethylene with water in the presence of phosphoric acid.

When the two carbon atoms of a double bond are not equivalent, the H of the HX compound adds to the carbon that has the greater number of directly attached hydrogen atoms, and X adds to the one with the fewer. (This generalization is called the Markovnikov rule, named after Russian chemist Vladimir Markovnikov, who proposed the rule in 1869.) Thus, when sulfuric acid (H₂SO₄) adds to propylene, the product is isopropyl hydrogen sulfate, not n-propyl hydrogen sulfate (CH₃CH₂CH₂OSO₃H). This is the first step in the industrial preparation of isopropyl alcohol, which is formed when isopropyl hydrogen sulfate is heated with water.

The term regioselective describes the preference for a reaction that occurs in one direction rather than another, as in the addition of sulfuric acid to propylene. A regiospecific reaction is one that is 100 percent regioselective. The Markovnikov rule expresses the regioselectivity to be expected in the addition of unsymmetrical reagents (such as HX) to unsymmetrical alkenes (such as H₂C=CHR).

Boron hydrides, compounds of the type R₂BH, add to alkenes to give organoboranes (hydroboration), which can be oxidized to alcohols with hydrogen peroxide (H₂O₂) (oxidation). The net result is the same as if H and ―OH add to the double bond with a regioselectivity opposite to the Markovnikov rule. The hydroboration-oxidation sequence is one of a large number of boron-based synthetic methods developed by American chemist Herbert C. Brown.

Vicinal diols, compounds with ―OH groups on adjacent carbons, are formed when alkenes react with certain oxidizing agents, especially potassium permanganate (KMnO₄) or osmium tetroxide (OsO₄). The most widely used methods employ catalytic amounts of OsO₄ in the presence of oxidizing agents such as tert-butyl hydroperoxide [(CH₃)₃COOH].

Alkenes are the customary starting materials from which epoxides, compounds containing a three-membered ring consisting of one oxygen atom and two carbon atoms, are made. The simplest epoxide, ethylene oxide (oxirane), is obtained by passing a mixture of ethylene and air (or oxygen) over a heated silver catalyst. Epoxides are useful intermediates for a number of transformations. Ethylene oxide, for example, is converted to ethylene glycol, which is used in the synthesis of polyester fibres and films and as the main component of automobile antifreeze. On a laboratory scale, epoxides are normally prepared by the reaction of an alkene and a peroxy acid.

Hydrocarbon. Formation of expoxides. Ethylene + oxygen yields ethylene oxide (and with the addition of water and heat) yields ethylene glycol.

Conjugated dienes undergo a novel and useful reaction known as the Diels-Alder cycloaddition. In this reaction, a conjugated diene reacts with an alkene to form a compound that contains a cyclohexene ring. The unusual feature of the Diels-Alder cycloaddition is that two carbon-carbon bonds are formed in a single operation by a reaction that does not require catalysts of any kind. The German chemists Otto Diels and Kurt Alder received the Nobel Prize for Chemistry in 1950 for discovering and demonstrating the synthetic value of this reaction.

Heterocyclic Compound, Hydrocarbon. the Diels-Alder cycloaddition. A conjugated diene reacts with an alkene to form a compound that contains a cyclohexene ring. 1,3-butadiene + propenal yields cyclohexene-4-carboxaldehyde.

Alkynes undergo addition with many of the same substances that react with alkenes. Hydrogenation of alkynes can be controlled so as to yield either an alkene or an alkane. Two molecules of H₂ add to the triple bond to give an alkane under the usual conditions of catalytic hydrogenation.

Hydrocarbon. Hydrogenation of alkynes can be controlled so as to yield either an alkene or an alkane. Two molecules of H2 add to the triple bond to give an alkane under the usual conditions of catalytic hydrogenation.

Special, less active (poisoned) catalysts have been developed that permit the reaction to be halted at the alkene stage, and the procedure is used as a method for the synthesis of alkenes. When stereoisomeric alkenes are possible reaction products, the cis isomer is formed almost exclusively.

Alkynes react with Br₂ or Cl₂ by first adding one molecule of the halogen to give a dihaloalkene and then a second to yield a tetrahaloalkane.

Hydrocarbon. Alkynes react with Br2 or Cl2 by first additing one molecule of the halogen to give a dihaloalkene and then a second to yield a tetrahaloalkane. 1-butyne yields 1,2-dibromo-1-butene yields 1,1,2,2-tetrabromobutane.

Compounds of the type HX, where X is an electronegative atom or group, also add to alkynes. When acetylene (HC≡CH) reacts with HCl, the product is vinyl chloride (CH₂=CHCl), and, when HCN adds to acetylene, the product is acrylonitrile (CH₂=CHCN). Both vinyl chloride and acrylonitrile are valuable starting materials for the production of useful polymers (see below Polymerization), but neither is prepared in significant quantities from acetylene, because each is available at lower cost from an alkene (vinyl chloride from ethylene and acrylonitrile from propylene).

Hydration of alkynes is unusual in that the initial product, called an enol and characterized by an H―O―C=C― group, is unstable under the conditions of its formation and is converted to an isomer that contains a carbonyl group.

Although they are very weak acids, acetylene and terminal alkynes are much more acidic than alkenes and alkanes. A hydrogen attached to a triply bonded carbon can be removed by a very strong base such as sodium amide (NaNH₂) in liquid ammonia as the solvent.

Hydrocarbon. Acetylene and terminal alkynes are more acidic than alkenes and alkanes. A hydrogen attached to a triply bonded carbon can be removed by a very strong base such as sodium amide in liquid ammonia as the solvent.

The sodium salt of the alkyne formed in this reaction is not normally isolated but is treated directly with an alkyl halide. The ensuing reaction proceeds with carbon-carbon bond formation and is used to prepare higher alkynes.

Hydrocarbon. 1-butynylsodium + bromomethane yields 2-pentyne + sodium bromide.

Polymerization

A single alkene molecule, called a monomer, can add to the double bond of another to give a product, called a dimer, having twice the molecular weight. In the presence of an acid catalyst, the monomer 2-methylpropene (C₄H₈), for example, is converted to a mixture of C₈H₁₆ alkenes (dimers) suitable for subsequent conversion to 2,2,4-trimethylpentane (isooctane).

Hydrocarbon. Polymerization. 2-methylpropene in the presence of an acid yields 2,4,4-trimethyl-1-penten + 2,4,4-trimethyl-2-pentene

If the process is repeated, trimers, and eventually polymers—substances composed of a great many monomer units—are obtained.

Approximately one-half of the ethylene produced each year is used to prepare the polymer polyethylene. Polyethylene is a mixture of polymer chains of different lengths, where n, the number of monomer units, is on the order of 1,000–5,000.

Hydrocarbon. Ethylene in the presence of a catalyst yields polyethylene.

The distinguishing characteristic of polyethylene is its resistance to attack by most substances. Its resemblance to an alkane in this respect is not surprising, because the polymer chain is nearly void of functional groups. Its ends may have catalyst molecules attached or may terminate in a double bond by loss of a hydrogen atom at the next-to-last carbon. The properties of a particular sample of polyethylene depend mainly on the catalyst used and the conditions under which polymerization occurs. A chain may be continuous, or it may sprout occasional branches of shorter chains. The more nearly continuous the chain, the greater is the density of the polymer.

Low-density polyethylene (LDPE) is obtained under conditions of free-radical polymerization, whereby polymerization is initiated by oxygen or peroxides under high pressure at roughly 200 °C (392 °F). Polyethylene, especially low-density polyethylene, is thermoplastic (softens and flows on heating) and can be extruded into sheets or films and molded into various shapes.

High-density polyethylene (HDPE) is obtained under conditions of coordination polymerization initiated by a mixture of titanium tetrachloride (TiCl₄) and triethylaluminum [(CH₃CH₂)₃Al]. Coordination polymerization was discovered by German chemist Karl Ziegler. Ziegler and Italian chemist Giulio Natta pioneered the development of Ziegler-Natta catalysts, for which they shared the 1963 Nobel Prize for Chemistry. The original Ziegler-Natta titanium tetrachloride-triethylaluminum catalyst has been joined by a variety of others. In addition to its application in the preparation of high-density polyethylene, coordination polymerization is the method by which ethylene oligomers, called linear α-olefins, and stereoregular polymers, especially polypropylene, are prepared.

Vinyl compounds, which are substituted derivatives of ethylene, can also be polymerized according to the following reaction:

Hydrocarbon. Vinyl compounds, which are substituted derivatives of ethylene, can be polymerized according to this reaction:

Polymerization of vinyl chloride (where X is Cl) gives polyvinyl chloride, or PVC, more than 27 million metric tons of which is used globally each year to produce pipes, floor tiles, siding for houses, gutters, and downspouts. Polymerization of styrene, X = C₆H₅ (a phenyl group derived from benzene; see below Aromatic hydrocarbons), yields polystyrene, a durable polymer used to make luggage, refrigerator casings, and television cabinets and which can be foamed and used as a lightweight packaging and insulating material. If X = CH₃, the product is polypropylene, which is used to make films, molded articles, and fibres. Acrylonitrile, X = CN, gives polyacrylonitrile for use in carpet fibres and clothing.

Diene polymers have an important application as rubber substitutes. Natural rubber (see above Natural occurrence) is a polymer of 2-methyl-1,3-butadiene (commonly called isoprene). Coordination polymerization conditions have been developed that convert isoprene to a polymer with properties identical to that of natural rubber.

Hydrocarbon. Coordination polymerization conditions have been developed that convert isoprene to a polymer with properties identical to that of natural rubber. 2-methyl-1,3-butadiene (isoprene) yields polyisoprene.

The largest portion of the synthetic rubber industry centres on styrene-butadiene rubber (SBR), which is a copolymer of styrene and 1,3-butadiene. Its major application is in automobile tires.

Hydrocarbon. formula reaction for styrene-butadiene rubber (SBR). 1,3-butadiene + styrene yields styrene-butadiene rubber

Alkyne polymerization is not nearly as developed nor as useful a procedure as alkene polymerization. The dimer of acetylene, vinylacetylene, is the starting material for the preparation of 2-chloro-1,3-butadiene, which in turn is polymerized to give the elastomer neoprene. Neoprene was the first commercially successful rubber substitute.

Hydrocarbon. Vinylacetylene is the starting material for the prepartion of 2-chloro-1,3-butadiene, which in turn is polymerized to give the elastomer neoprene. Neoprene was the first commercially successful rubber substitute.

Aromatic hydrocarbons

Benzene (C₆H₆), the simplest aromatic hydrocarbon, was first isolated in 1825 by English chemist Michael Faraday from the oily residues left from illuminating gas. In 1834 it was prepared from benzoic acid (C₆H₅CO₂H), a compound obtained by chemical degradation of gum benzoin, the fragrant balsam exuded by a tree that grows on the island of Java, Indonesia. Similarly, the hydrocarbon toluene (C₆H₅CH₃) received its name from tolu balsam, a substance isolated from a Central American tree and used in perfumery. Thus benzene, toluene, and related hydrocarbons, while not particularly pleasant-smelling themselves, were classified as aromatic because they were obtained from fragrant substances. Joseph Loschmidt, an Austrian chemist, recognized in 1861 that most aromatic substances have formulas that can be derived from benzene by replacing one or more hydrogens by other atoms or groups. The term aromatic thus came to mean any compound structurally derived from benzene. Use of the term expanded with time to include properties, especially that of special stability, and eventually aromaticity came to be defined in terms of stability alone. The modern definition states that a compound is aromatic if it is significantly more stable than would be predicted on the basis of the most stable Lewis structural formula written for it. (This special stability is related to the number of electrons contained in a cyclic conjugated system; see below Arenes: Structure and bonding.) All compounds that contain a benzene ring possess special stability and are classified as benzenoid aromatic compounds. Certain other compounds lack a benzene ring yet satisfy the criterion of special stability and are classified as nonbenzenoid aromatic compounds.

Arenes

These compounds are hydrocarbons that contain a benzene ring as a structural unit. In addition to benzene, other examples include toluene and naphthalene.

Hydrocarbon. Structural formulas for 3 Arenes: benzene, toluene, and naphthalene.

(Hydrogen atoms connected to the benzene ring are shown for completeness in the above structural formulas. The more usual custom, which will be followed hereafter, omits them.)