Isomerization
In chemistry, isomerization or isomerisation is the process in which a molecule, polyatomic ion or molecular fragment is transformed into an isomer with a different chemical structure.<ref>Template:GoldBookRef</ref> Enolization is an example of isomerization, as is tautomerization.<ref>Template:Cite book</ref>
When the activation energy for the isomerization reaction is sufficiently small, both isomers can often be observed and the equilibrium ratio will shift in a temperature-dependent equilibrium with each other. Many values of the standard free energy difference, <math>\Delta G^\circ</math>, have been calculated, with good agreement between observed and calculated data.<ref>How to Compute Isomerization Energies of Organic Molecules with Quantum Chemical Methods Stefan Grimme, Marc Steinmetz, and Martin Korth J. Org. Chem.; 2007; 72(6) pp 2118 - 2126; (Article) {{#invoke:doi|main}}</ref>
Examples and applicationsEdit
AlkanesEdit
Skeletal isomerization occurs in the cracking process, used in the petrochemical industry to convert straight chain alkanes to isoparaffins as exemplified in the conversion of normal octane to 2,5-dimethylhexane (an "isoparaffin"):<ref name=Ullmann>Template:Cite book</ref>
Fuels containing branched hydrocarbons are favored for internal combustion engines for their higher octane rating.<ref>Template:Cite encyclopedia</ref> Diesel engines however operate better with straight-chain hydrocarbons.
AlkenesEdit
Cis vs transEdit
Trans-alkenes are about 1 kcal/mol more stable than cis-alkenes. An example of this effect is cis- vs trans-2-butene. The difference is attributed to unfavorable non-bonded interactions in the cis isomer. This effects helps to explain the formation of trans-fats in food processing. In some cases, the isomerization can be reversed using UV-light. The trans isomer of resveratrol converts to the cis isomer in a photochemical reaction.<ref>Template:Cite journal</ref>
Terminal vs internalEdit
Terminal alkenes prefer to isomerize to internal alkenes:
The conversion essentially does not occur in the absence of metal catalysts. This process is employed in the Shell higher olefin process to convert alpha-olefins to internal olefins, which are subjected to olefin metathesis.
Other organic examplesEdit
Isomerism is a major topic in sugar chemistry. Glucose, the most common sugar, exists in four forms.
| Isomers of Template:Sm-glucose | ||
|---|---|---|
| File:Alpha-D-Glucofuranose.svgTemplate:Pbα-Template:Sm-glucofuranose | File:Beta-D-Glucofuranose.svgTemplate:Pbβ-Template:Sm-glucofuranose | |
| File:Alpha-D-Glucopyranose.svgTemplate:Pbα-Template:Sm-glucopyranose | File:Beta-D-Glucopyranose.svgTemplate:Pbβ-Template:Sm-glucopyranose | |
Aldose-ketose isomerism, also known as Lobry de Bruyn–van Ekenstein transformation, provides an example in saccharide chemistry.Template:Citation needed
Inorganic and organometallic chemistryEdit
The compound with the formula [[Cyclopentadienyliron dicarbonyl dimer|Template:Chem2]] exists as three isomers in solution. In one isomer the CO ligands are terminal. When a pair of CO are bridging, cis and trans isomers are possible depending on the location of the C5H5 groups.<ref name=":2">Template:Cite journal</ref>
Another example in organometallic chemistry is the linkage isomerization of decaphenylferrocene, Template:Chem2.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>
Kinetic classificationEdit
From the kinetic viewpoint, isomerizations can be classified into two categories.<ref>Template:Cite book</ref> Cases in the first category involve transformations between equivalent structures. Most chemical species are in principle susceptible to such processes. Many such cases involve fluxional molecules, such as the cyclohexane ring flip (chair inversion), the pyramidal inversion of ammonia, the Berry pseudorotation in pentacoordinate compounds (e.g. PF5, Fe(CO)5), the Cope rearrangements of bullvalene or the Ray-Dutt/Bailar twists for the racemization of octahedral complexes with three bidentate chelate rings (helical chirality).
In the second broad category of isomerizations, the isomers are nonequivalent. Examples include tautomerizations (keto-enol, lactam-lactim, amide-imidic, enamine-imine, nitroso-oxime, ketene-ynol, etc) in which one isomer is more stable than the other.
This scheme leads to the following system of differential rate equations: