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Corey–Fuchs reaction

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Corey–Fuchs reaction
Named after Elias James Corey
Philip L. Fuchs
Reaction type Substitution reaction
Identifiers
Organic Chemistry Portal corey-fuchs-reaction
RSC ontology ID RXNO:0000146

The Corey–Fuchs reaction, also known as the Ramirez–Corey–Fuchs reaction, is a series of chemical reactions designed to transform an aldehyde into an alkyne.[1][2][3] The formation of the 1,1-dibromoolefins via phosphine-dibromomethylenes was originally discovered by Desai, McKelvie and Ramirez.[4] The phosphine can be partially substituted by zinc dust, which can improve yields and simplify product separation.[1] The second step of the reaction to convert dibromoolefins to alkynes is known as Fritsch–Buttenberg–Wiechell rearrangement. The overall combined transformation of an aldehyde to an alkyne by this method is named after its developers, American chemists Elias James Corey and Philip L. Fuchs.

The Corey–Fuchs reaction
The Corey–Fuchs reaction

By suitable choice of base, it is often possible to stop the reaction at the 1-bromoalkyne, a useful functional group for further transformation.

Reaction mechanism

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The Corey–Fuchs reaction is based on a special case of the Wittig reaction, where two equivalents of triphenylphosphine are used with carbon tetrabromide to produce the triphenylphosphine-dibromomethylene ylide.[2]

Step 1 of the Corey-Fuchs reaction, generating the active ylide
Step 1 of the Corey-Fuchs reaction, generating the active ylide

This ylide undergoes a Wittig reaction when exposed to an aldehyde. Alternatively, using a ketone generates a gem-dibromoalkene.

Step 2 in the Corey-Fuchs reaction, doing the Wittig to make the dibromoalkene
Step 2 in the Corey-Fuchs reaction, doing the Wittig to make the dibromoalkene

The second part of the reaction converts the isolable gem-dibromoalkene intermediate to the alkyne. Deuterium-labelling studies show that this step proceeds through a carbene mechanism. Lithium-Bromide exchange is followed by α-elimination to afford the carbene. 1,2-shift then affords the deuterium-labelled terminal alkyne.[3] The 50% H-incorporation could be explained by deprotonation of the (acidic) terminal deuterium with excess BuLi.

Deuterium-labelling shows the involvement of carbenes in the second part of the Corey-Fuchs reaction.
Deuterium-labelling shows the involvement of carbenes in the second part of the Corey-Fuchs reaction.

See also

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References

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  1. ^ Kurti 1 Czako 2, Laszlo 1 Barbara 2 (15 September 2005). Strategic Applications of Named Reactions in Organic Synthesis. Elsevier. pp. 104–105. ISBN 0-12-429785-4.{{cite book}}: CS1 maint: numeric names: authors list (link)
  2. ^ Bew, S. P. (2005-01-01), Katritzky, Alan R.; Taylor, Richard J. K. (eds.), "5.02 - Carboxylic Acids", Comprehensive Organic Functional Group Transformations II, Oxford: Elsevier, pp. 19–125, doi:10.1016/b0-08-044655-8/00092-1, ISBN 978-0-08-044655-4, retrieved 2024-10-15
  3. ^ Sahu, Bichismita; Muruganantham, Rajendran; Namboothiri, Irishi N. N. (2007). "Synthetic and Mechanistic Investigations on the Rearrangement of 2,3-Unsaturated 1,4-Bis(alkylidene)carbenes to Enediynes". European Journal of Organic Chemistry. 2007 (15): 2477–2489. doi:10.1002/ejoc.200601137. ISSN 1434-193X.
  1. ^ Corey, E. J.; Fuchs, P. L. Tetrahedron Lett. 1972, 13, 3769–3772. doi:10.1016/S0040-4039(01)94157-7
  2. ^ Mori, M.; Tonogaki, K.; Kinoshita, A. Organic Syntheses, Vol. 81, p. 1 (2005). (Article Archived 2011-05-14 at the Wayback Machine)
  3. ^ Marshall, J. A.; Yanik, M. M.; Adams, N. D.; Ellis, K. C.; Chobanian, H. R. Organic Syntheses, Vol. 81, p. 157 (2005). (Article Archived 2011-05-14 at the Wayback Machine)
  4. ^ N. B. Desai, N. McKelvie, F. Ramirez JACS, Vol. 84, p. 1745-1747 (1962). doi:10.1021/ja00868a057
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