Catalytic oxidation

Catalytic oxidation are processes that oxidize compounds using catalysts. Common applications involve oxidation of organic compounds by the oxygen in air. Such processes are conducted on a large scale for the remediation of pollutants, production of valuable chemicals, and the production of energy.^[1]

An illustrative catalytic oxidation is the conversion of methanol to the more valuable compound formaldehyde using oxygen in air:

2 CH₃OH + O₂ → 2CH₂O + 2 H₂O

This conversion is very slow in the absence of catalysts. Typical oxidation catalysts are metal oxides and metal carboxylates.

Examples

Industrially important examples include both inorganic and organic substrates.

Substrate	Process	Catalyst (homogeneous or heterogeneous	Product	Application
sulfur dioxide	contact process	vanadium pentoxide (heterogeneous)	sulfuric acid	fertilizer production
ammonia	Ostwald process	platinum (heterogeneous)	nitric acid	basic chemicals, TNT
hydrogen sulfide	Claus process	vanadium pentoxide (heterogeneous)	sulfur	remediation of byproduct of oil refinery
methane, ammonia	Andrussow process	platinum (heterogeneous)	hydrogen cyanide	basic chemicals, gold mining extractant
ethylene	epoxidation	mixed Ag oxides (heterogeneous)	ethylene oxide	basic chemicals, surfactants
cyclohexane	K-A process	Co and Mn salts (homogeneous)	cyclohexanol cyclohexanone	nylon precursor
ethylene	Wacker process	Pd and Cu salts (homogeneous)	acetaldehyde	basic chemicals
para-xylene	terephthalic acid synthesis	Mn and Co salts (homogeneous)	terephthalic acid	plastic precursor
propylene	allylic oxidation	Mo-oxides (heterogeneous)	acrylic acid	plastic precursor
propylene, ammonia	SOHIO process	Bi-Mo-oxides (heterogeneous)	acrylonitrile	plastic precursor
methanol	Formox process	Fe-Mo-oxides (heterogeneous)	formaldehyde	basic chemicals, alkyd resins
butane	Maleic anhydride process	vanadium phosphates (heterogeneous)	maleic anhydride	plastics, alkyd resins
ethylene	OMEGA process		ethylene glycol	Coolant, antifreeze, plastics

Catalysts

Applied catalysis

Oxidation catalysis is conducted by both heterogeneous catalysis and homogeneous catalysis. In the heterogeneous processes, gaseous substrate and oxygen (or air) are passed over solid catalysts. Typical catalysts are platinum, and redox-active oxides of iron, vanadium, and molybdenum. In many cases, catalysts are modified with a host of additives or promoters that enhance rates or selectivities.

Important homogeneous catalysts for the oxidation of organic compounds are carboxylates of cobalt, iron, and manganese. To confer good solubility in the organic solvent, these catalysts are often derived from naphthenic acids and ethylhexanoic acid, which are highly lipophilic. These catalysts initiate radical chain reactions, autoxidation that produce organic radicals that combine with oxygen to give hydroperoxide intermediates. Generally the selectivity of oxidation is determined by bond energies. For example, benzylic C-H bonds are replaced by oxygen faster than aromatic C-H bonds.^[2]

Fine chemicals

Many selective oxidation catalysts have been developed for producing fine chemicals of pharmaceutical or academic interest. Nobel Prize–winning examples are the Sharpless epoxidation and the Sharpless dihydroxylation.

Biological catalysis

Catalytic oxidations are common in biology, especially since aerobic life subsists on energy obtained by oxidation of organic compounds by air. In contrast to the industrial processes, which are optimized for producing chemical compounds, energy-producing biological oxidations are optimized to produce energy. Many metalloenzymes mediate these reactions.

Fuel cells, etc

Fuel cells rely on oxidation of organic compounds (or hydrogen) using catalysts. Catalytic heaters generate flameless heat from a supply of combustible fuel and oxygen from air as oxidant.

References

↑ Gerhard Franz, Roger A. Sheldon "Oxidation" in Ullmann's Encyclopedia of Industrial Chemistry, Wiley-VCH, Weinheim, 2000 doi:10.1002/14356007.a18_261
↑ Mario G. Clerici, Marco Ricci and Giorgio Strukul "Formation of C–O Bonds by Oxidation" in Metal-catalysis in Industrial Organic Processes Gian Paolo Chiusoli, Peter M Maitlis, Eds. 2006, RSC. ISBN 978-0-85404-862-5.

External links

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[1] Gerhard Franz, Roger A. Sheldon "Oxidation" in Ullmann's Encyclopedia of Industrial Chemistry, Wiley-VCH, Weinheim, 2000 doi:10.1002/14356007.a18_261

[2] Mario G. Clerici, Marco Ricci and Giorgio Strukul "Formation of C–O Bonds by Oxidation" in Metal-catalysis in Industrial Organic Processes Gian Paolo Chiusoli, Peter M Maitlis, Eds. 2006, RSC. ISBN 978-0-85404-862-5.