Norrish reaction

A Norrish reaction, named after Ronald George Wreyford Norrish, is a photochemical reaction taking place with ketones and aldehydes. Such reactions are subdivided into Norrish type I reactions and Norrish type II reactions.^[1] While of limited synthetic utility these reactions are important in the photo-oxidation of polymers such as polyolefins,^[2] polyesters, certain polycarbonates and polyketones.

Type I

The Norrish type I reaction is the photochemical cleavage or homolysis of aldehydes and ketones into two free radical intermediates (α-scission). The carbonyl group accepts a photon and is excited to a photochemical singlet state. Through intersystem crossing the triplet state can be obtained. On cleavage of the α-carbon bond from either state, two radical fragments are obtained.^[3] The size and nature of these fragments depends upon the stability of the generated radicals; for instance, the cleavage of 2-butanone largely yields ethyl radicals in favor of less stable methyl radicals.^[4]

 

Norrish type I reaction

Several secondary reaction modes are open to these fragments depending on the exact molecular structure.

• The fragments can simply recombine to the original carbonyl compound, with racemisation at the α-carbon.
• The acyl radical can lose a molecule of carbon monoxide, forming a new carbon radical at the other α-carbon, followed by formation of a new carbon–carbon bond between the radicals.^[3] The ultimate effect is simple extraction of the carbonyl unit from the carbon chain. The rate and yield of this product depends upon the bond-dissociation energy of the ketone's α substituents. Typically the more α substituted a ketone is, the more likely the reaction will yield products in this way.^[5][6]
• The abstraction of an α-proton from the carbonyl fragment may form a ketene and an alkane.
• The abstraction of a β-proton from the alkyl fragment may form an aldehyde and an alkene.

 

Norrish type I reaction

The synthetic utility of this reaction type is limited, for instance it often is a side reaction in the Paternò–Büchi reaction. One organic synthesis based on this reaction is that of bicyclohexylidene.^[7]

Type II

A Norrish type II reaction is the photochemical intramolecular abstraction of a γ-hydrogen (a hydrogen atom three carbon positions removed from the carbonyl group) by the excited carbonyl compound to produce a 1,4-biradical as a primary photoproduct.^[8] Norrish first reported the reaction in 1937.^[9]

 

Norrish type II reaction

Secondary reactions that occur are fragmentation (β-scission) to form an alkene and an enol (which will rapidly tautomerise to a carbonyl), or intramolecular recombination of the two radicals to a substituted cyclobutane (the Norrish–Yang reaction).^[10]

Scope

The Norrish reaction has been studied in relation to environmental chemistry with respect to the photolysis of the aldehyde heptanal, a prominent compound in Earth's atmosphere.^[11] Photolysis of heptanal in conditions resembling atmospheric conditions results in the formation of 1-pentene and acetaldehyde in 62% chemical yield together with cyclic alcohols (cyclobutanols and cyclopentanols) both from a Norrish type II channel and around 10% yield of hexanal from a Norrish type I channel (the initially formed n-hexyl radical attacked by oxygen).

In one study^[12] the photolysis of an acyloin derivative in water in presence of hydrogen tetrachloroaurate (HAuCl₄) generated nanogold particles with 10 nanometer diameter. The species believed to responsible for reducing Au³⁺ to Au^0[13] is the Norrish generated ketyl radical.

 

Norrish application nanogold synthesis

Leo Paquette's 1982 synthesis of dodecahedrane involves three separate Norrish-type reactions in its approximately 29-step sequence.

An example of a synthetically useful Norrish type II reaction can be found early in the total synthesis of the biologically active cardenolide ouabagenin by Phil Baran and coworkers.^[14] The optimized conditions minimize side reactions, such as the competing Norrish type I pathway, and furnish the desired intermediate in good yield on a multi-gram scale.

 

Type II Norrish reaction in Phil Baran's total synthesis of the biologically active cardenolide ouabagenin.

See also

• Photo-Fries rearrangement - a related reaction of aromatic carbonyls
• McLafferty rearrangement - similar to a Type II Norrish reaction. Caused by electron impact ionization rather than light
• Carbon monoxide-releasing molecules

References

1. Named Organic Reactions, 2nd Edition, Thomas Laue and Andreas Plagens, John Wiley & Sons: Chichester, England, New York, 2005. 320 pp. ISBN 0-470-01041-X
2. Grause, Guido; Chien, Mei-Fang; Inoue, Chihiro (November 2020). "Changes during the weathering of polyolefins". Polymer Degradation and Stability. 181: 109364. doi:10.1016/j.polymdegradstab.2020.109364. S2CID 225243217.
3. "IUPAC Gold Book - Norrish Type I photoreaction". IUPAC. 24 February 2014. doi:10.1351/goldbook.N04219. Retrieved 31 March 2014. {{cite journal}}: Cite journal requires |journal= (help)
4. Blacet, F. E.; N. Pitts Jr., James (1950). "Methyl Ethyl Ketone Photochemical Processes". Journal of the American Chemical Society. 72 (6): 2810–2811. doi:10.1021/ja01162a544.
5. Yang, Nien-Chu; D. Feit, Eugene; Hui, Man Him; Turro, Nicholas J.; Dalton, Christopher (1970). "Photochemistry of di-tert-butyl ketone and structural effects on the rate and efficiency of intersystem crossing of aliphatic ketones". Journal of the American Chemical Society. 92 (23): 6974–6976. doi:10.1021/ja00726a046.
6. Abuin, E.B.; Encina, M.V.; Lissi, E.A. (1972). "The photolysis of 3-pentanone". Journal of Photochemistry. 1 (5): 387–396. doi:10.1016/0047-2670(72)80036-4.
7. Bicyclohexylidene Nicholas J. Turro, Peter A. Leermakers, and George F. Vesley Organic Syntheses, Coll. Vol. 5, p.297 (1973); Vol. 47, p.34 (1967) Online article.
8. "IUPAC Gold Book - Norrish Type II photoreaction". IUPAC. 24 February 2014. doi:10.1351/goldbook.N04218. Retrieved 31 March 2014. {{cite journal}}: Cite journal requires |journal= (help)
9. Norrish, R. G. W.; Bamford, C. H. (31 July 1937). "Photo-decomposition of Aldehydes and Ketones". Nature. 140 (3535): 195–6. Bibcode:1937Natur.140..195N. doi:10.1038/140195b0. S2CID 4104669.
10. "IUPAC Gold Book - Norrish–Yang reaction". IUPAC. 24 February 2014. doi:10.1351/goldbook.NT07427. Retrieved 31 March 2014. {{cite journal}}: Cite journal requires |journal= (help)
11. Photolysis of Heptanal Suzanne E. Paulson, De-Ling Liu, Grazyna E. Orzechowska, Luis M. Campos, and K. N. Houk J. Org. Chem.; 2006; 71(17) pp 6403 - 6408; (Article) doi:10.1021/jo060596u
12. Facile Photochemical Synthesis of Unprotected Aqueous Gold Nanoparticles Katherine L. McGilvray, Matthew R. Decan, Dashan Wang, and Juan C. Scaiano J. Am. Chem. Soc.; 2006; 128(50) pp 15980 - 15981; (Communication) doi:10.1021/ja066522h
13. Technically Au³⁺ is reduced to Au²⁺ which then forms Au⁺ and Au³⁺ by disproportionation followed by final reduction of Au¹⁺ to Au^o
14. Renata, H.; Zhou, Q.; Baran, P. S. (3 January 2013). "Strategic Redox Relay Enables A Scalable Synthesis of Ouabagenin, A Bioactive Cardenolide". Science. 339 (6115): 59–63. Bibcode:2013Sci...339...59R. doi:10.1126/science.1230631. PMC 4365795. PMID 23288535.