Alkene

An alkene is one of the three classes of unsaturated hydrocarbons that contain at least one carbon-carbon double bond and have the general molecular formula of C_nH_2n (the other two being alkynes and areness).

The simplest alkene is C₂H₄, which has the common name "ethylene" and the IUPAC name "ethene".

Structure of Alkenes

Shape of Alkenes

As predicted by the VSEPR model of electron pair replusion (see covalent bond), the bond angles about each carbon in a double bond are about 120°, although the angle may be larger because of strain introduced by nonbonded interactions created by groups attached to the carbons of the double bond. For example, the C-C-C bond angle in propene (propylene) is 123.9°.

Molecular Geometry Carbon-Carbon Double Bond

Like single covalent bonds, double bonds can be described in terms of overlapping atomic orbitals, except that unlike a single bond (which consist of a single sigma bond), a carbon-carbon double bond consists of one sigma bond and one pi bond.

Each carbon of the double bond uses its three sp² hybrid orbitals to form sigma bonds to three atoms. The unhybridized 2p atomic orbitals, which lie perpendicular to the plane created by the axes of the three sp² hybrid orbitals, combine to form the pi bond.

Because it requires a large amount of energy to break a pi bond (264 kJ/mol in ethylene), rotation about the carbon-carbon double bond is very difficult and therefore severely restricted.

Physical properties

The same as alkanes.

Physical state depends on molecular mass.

Chemical properties

Alkenes are relatively stable compounds, but are more reactive than alkanes.

Reactions

Synthesis

The most common industrial synthesis path for alkenes is cracking of petroleum.

Alkenes can be synthesized from alcohols via an elimination reaction that removes one water molecule:
H₃C-CH₂-OH + H₂SO₄ → H₃C-CH₂-O-SO₃H + H₂O → H₂C=CH₂ + H₂SO₄

Catalytic synthesis of higher α-alkenes can be achieved by a reaction of ethene with triethylaluminium, an organometallic compound in the presence of nickel, cobalt or platinum.

Addition reactions

Catalytic addition of hydrogen

Catalytic hydrogenation of alkenes produce the corresponding alkanes. The reaction is carried out under pressure in the presence of a metallic catalyst. Common industrial catalysts are based on platinum, nickel or palladium, for laboratory syntheses, Raney's nickel is often employed. This is an alloy of nickel and aluminium.

This is the catalytic hydrogenation of ethylene to yield ethane:

CH₂=CH₂ + H₂ → CH₃-CH₃

Electrophilic addition

Most addition reactions to alkenes follow the mechanism of electrophilic addition.

Halogenation: Addition of elementary bromine or chlorine to alkenes yield vicinal Dibromo- and dichloroalkenes, respectively. The decoloration of a solution of bromine in water is an analytical test for the presence of alkenes:
CH₂=CH₂ + Br₂ → BrCH₂-CH₂Br
Hydrohalogenation: Addition of hydrohalic acids like HCl or HBr to alkenes yield the corresponding haloalkanes.
CH₃-CH=CH₂ + HBr → CH₃-CHBr-CH₃
If the two carbon atoms at the double bond are linked to a different number of hydrogen atoms, the halogen is found preferentially at the carbon with less hydrogen substituents (Markovnikov's rule).
Addition of a carbene or carbenoid yields the corresponding cyclopropane
Oxidation
In the presence of oxygen, alkenes burn with a bright flame to carbon dioxide and water.
Catalytic oxidation with oxygen or the reaction with percarboxylic acids yields epoxides
Reaction with ozone leads to the breaking of the double bond, yielding two aldehydes or ketones
R₁-CH=CH-R₂ + O₃ → R₁-CHO + R₂-CHO + H₂O
This reaction can be used to determine the position of a double bond in an unknown alkene.
Polymerisation
Polymerization of alkenes is an economically important reaction which yields polymers of high industrial value, such as the plastics polyethylene and polypropylene. Polymerization can either proceed via a free-radical or an ionic mechanism. For detail regarding the reaction mechanisms, see the polymerization article.
Nomenclature of Alkenes

IUPAC Names

To form the root of the IUPAC names for alkenes, simply change the -an- infix of the parent to -en-. For example, CH₃-CH₃ is the alkane ethANe. The name of CH₂=CH₂ is therefore ethENe.

In higher alkenes, where isomers exist that differ in location of the double bond, the following numbering system is used:

Number the longest carbon chain the contains the double bond in the direction that gives the carbon atoms of the double bond the lowest possible numbers.

Indicate the location of the double bond by the location of its first carbon

Name branched or substituted alkenes in a manner similar to alkanes.

Number the carbon atoms, locate and name substituent groups, locate the double bond, and name the main chain

Common Names

Despite the precision and universal acceptance of the IUPAC naming system, some alkenes are known almost exclusively by their common names:

Alkene

Alkene

Structure of Alkenes

Shape of Alkenes

Molecular Geometry Carbon-Carbon Double Bond

Physical properties

Chemical properties

Reactions

Synthesis

Addition reactions

Catalytic addition of hydrogen

Electrophilic addition

Oxidation

Polymerisation

Nomenclature of Alkenes

IUPAC Names

Common Names

See also: