Mesitylene


Mesitylene or 1,3,5-trimethylbenzene is a derivative of benzene with three methyl substituents positioned symmetrically around the ring. The other two isomeric trimethylbenzenes are 1,2,4-trimethylbenzene and 1,2,3-trimethylbenzene. All three compounds have the formula C6H33, which is commonly abbreviated C6H3Me3. Mesitylene is a colourless liquid with sweet aromatic odor. It is a component of coal tar, which is its traditional source. It is a precursor to diverse fine chemicals. The mesityl group is a substituent with the formula C6H3Me3 and is found in various other compounds.

Preparation

Mesitylene is prepared by equilibration of xylene over solid acid catalyst:
Trimerization of acetone via aldol condensation, which is catalyzed and dehydrated by sulfuric acid affords a mixture of 1,3,5- and 1,2,4-trimethylbenzenes.

Reactions

Oxidation of mesitylene with nitric acid affords trimesic acid, C6H33. Using manganese dioxide, a milder oxidising agent, 3,5-dimethylbenzaldehyde is formed. Mesitylene is oxidised by trifluoroperacetic acid to produce mesitol.

Applications

Mesitylene is mainly used as a precursor to 2,4,6-trimethylaniline, a precursor to colorants. This derivative is prepared by selective mononitration of mesitylene, avoiding oxidation of the methyl groups.
Additive and component of some avgas blends.

Niche uses

Mesitylene is used in the laboratory as a specialty solvent. It can also act as a ligand in organometallic chemistry, one example being the organomolybdenum complex which can be prepared from molybdenum hexacarbonyl.
In the electronics industry, mesitylene has been used as a developer for photopatternable silicones due to its solvent properties.
The three aromatic hydrogen atoms of mesitylene are in identical chemical shift environments. Therefore, they only give a single peak near 6.8 ppm in the 1H NMR spectrum; the same is also true for the nine methyl protons, which give a singlet near 2.3 ppm. For this reason, mesitylene is sometimes used as an internal standard in NMR samples that contain aromatic protons.
Uvitic acid is obtained by oxidizing mesitylene or by condensing pyruvic acid with baryta water.
The Gattermann reaction can be simplified by replacing the HCN/AlCl3 combination with zinc cyanide. Although it is highly toxic, Zn2 is a solid, making it safer to work with than gaseous hydrogen cyanide. The Zn2 reacts with the HCl to form the key HCN reactant and Zn2 that serves as the Lewis-acid catalyst in-situ. An example of the Zn2 method is the synthesis of mesitaldehyde from mesitylene.

History

Mesitylene was first prepared in 1837 by Robert Kane, an Irish chemist, by heating acetone with concentrated sulfuric acid. He named his new substance "mesitylene" because the German chemist Carl Reichenbach had named acetone "mesit", and Kane believed that his reaction had dehydrated mesit, converting it to an alkene, "mesitylene". However, Kane's determination of the chemical composition of mesitylene was incorrect. The correct empirical formula was provided by August W. von Hofmann in 1849. In 1866 Adolf von Baeyer showed that mesitylene's structure was consistent with that of 1,3,5-trimethylbenzene; however, conclusive proof that mesitylene was identical to 1,3,5-trimethylbenzene was provided by Albert Ladenburg in 1874.

Mesityl group

The group 3C6H2- is called mesityl. Mesityl derivatives, e.g. tetramesityldiiron, are typically prepared from the Grignard reagent 3C6H2MgBr. Due to its large steric demand, the mesityl group is used as a large blocking group in asymmetric catalysis and organometallic chemistry. Larger analogues with even greater steric demand, for example 2,6-diisopropylphenyl and the analogously named Tripp and supermesityl groups, may be even more effective toward achieving these goals.

Safety and the environment

Mesitylene is also a major urban volatile organic compound which results from combustion. It plays a significant role in aerosol and tropospheric ozone formation as well as other reactions in atmospheric chemistry.