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Aldol condensation

From Wikipedia, the free encyclopedia
Aldol condensation
Reaction type Condensation reaction
Reaction
Ketone or Aldehyde
+
Ketone or Aldehyde
α,β-unsaturated Aldehyde
or
α,β-unsaturated Ketone
Συνθήκες
Temperature
+Δ, ~100°C[a]
Catalyst
OH or H+
Identifiers
Organic Chemistry Portal aldol-condensation
RSC ontology ID RXNO:0000017

An aldol condensation is a condensation reaction in organic chemistry in which two carbonyl moieties (of aldehydes or ketones) react to form a β-hydroxyaldehyde or β-hydroxyketone (an aldol reaction), and this is then followed by dehydration to give a conjugated enone.

The overall reaction equation is as follows (where the Rs can be H) Aldol condensation overview

Aldol condensations are important in organic synthesis and biochemistry as ways to form carbon–carbon bonds.[2][3][4][5]

In its usual form, it involves the nucleophilic addition of a ketone enolate to an aldehyde to form a β-hydroxy ketone, or aldol (aldehyde + alcohol), a structural unit found in many naturally occurring molecules and pharmaceuticals.[6][7][8]

The Aldol reaction
The Aldol reaction

The term aldol condensation is also commonly used, especially in biochemistry, to refer to just the first (addition) stage of the process—the aldol reaction itself—as catalyzed by aldolases. However, the first step is formally an addition reaction rather than a condensation reaction because it does not involve the loss of a small molecule.

Mechanism

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The first part of this reaction is an Aldol reaction, the second part a dehydration—an elimination reaction (Involves removal of a water molecule or an alcohol molecule). Dehydration may be accompanied by decarboxylation when an activated carboxyl group is present. The aldol addition product can be dehydrated via two mechanisms; a strong base like potassium t-butoxide, potassium hydroxide or sodium hydride deprotonates the product to an enolate, which eliminates via the E1cB mechanism,[9][10] while dehydration in acid proceeds via an E1 reaction mechanism. Depending on the nature of the desired product, the aldol condensation may be carried out under two broad types of conditions: kinetic control or thermodynamic control.[11] Both ketones and aldehydes are suitable for aldol condensation reactions. In the examples below, aldehydes are used.

Base-catalyzed aldol condensation

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The mechanism for base-catalyzed aldol condensation can be seen in the image below.
A mechanism for aldol condensation in basic conditions, which occurs via enolate intermediates and E1CB elimination.
A mechanism for aldol condensation in basic conditions, which occurs via enolate intermediates and E1CB elimination.
The process begins when a free hydroxide (strong base) strips the highly acidic proton at the alpha carbon of the aldehyde. This deprotonation causes the electrons from the C-H bond to shift and create a new C-C pi bond. The new pi bond then acts as a nucleophile and attacks the remaining aldehyde in the solution, resulting in the formation of a new C-C bond and regeneration of the base catalyst.
In the second part of the reaction, the presence of base leads to elimination of water and formation of a new C-C pi bond. The product is referred to as the aldol condensation product.

Acid-catalyzed aldol condensation

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The mechanism for acid-catalyzed aldol condensation can be seen in the image below.
A mechanism for aldol condensation in acidic conditions, which occurs through enol intermediates and an elimination reaction.
A mechanism for aldol condensation in acidic conditions, which occurs through enol intermediates and an elimination reaction.
Animation zum basenkat. Reaktionsmechanismus der Aldolkondensation Animation zum säurekat. Reaktionsmechanismus der Aldolkondensation
animation, base catalyzed animation, acid catalyzed

Crossed aldol condensation

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A crossed aldol condensation is a result of two dissimilar carbonyl compounds containing α-hydrogen(s) undergoing aldol condensation. Ordinarily, this leads to four possible products as either carbonyl compound can act as the nucleophile and self-condensation is possible, which makes a synthetically useless mixture. However, this problem can be avoided if one of the compounds does not contain an α-hydrogen, rendering it non-enolizable. In an aldol condensation between an aldehyde and a ketone, the ketone acts as the nucleophile, as its carbonyl carbon does not possess high electrophilic character due to the +I effect and steric hindrance. Usually, the crossed product is the major one. Any traces of the self-aldol product from the aldehyde may be disallowed by first preparing a mixture of a suitable base and the ketone and then adding the aldehyde slowly to the said reaction mixture. Using too concentrated base could lead to a competing Cannizzaro reaction.[12]

Examples

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The Aldox process, developed by Royal Dutch Shell and Exxon, converts propene and syngas to 2-ethylhexanol via hydroformylation to butyraldehyde, aldol condensation to 2-ethylhexanal and finally hydrogenation.[13]

Aldox process

Pentaerythritol is produced on a large scale beginning with crossed aldol condensation of acetaldehyde and three equivalents of formaldehyde to give pentaerythrose, which is further reduced in a Cannizzaro reaction.[14]

Pentaerythritol Synthesis

Scope

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Ethyl 2-methylacetoacetate and campholenic aldehyde react in an Aldol condensation.[15] The synthetic procedure[16] is typical for this type of reaction. In the process, in addition to water, an equivalent of ethanol and carbon dioxide are lost in decarboxylation.

Aldol condensation of Ethyl 2-methylacetoacetate and campholenic aldehyde.

Ethyl glyoxylate 2 and glutaconate (diethyl-2-methylpent-2-enedioate) 1 react to isoprenetricarboxylic acid 3 (isoprene (2-methylbuta-1,3-diene) skeleton) with sodium ethoxide. This reaction product is very unstable with initial loss of carbon dioxide and followed by many secondary reactions. This is believed to be due to steric strain resulting from the methyl group and the carboxylic group in the cis-dienoid structure.[17]

Isoprenetricarboxylic acid
Isoprenetricarboxylic acid

Occasionally, an aldol condensation is buried in a multistep reaction or in catalytic cycle as in the following example:[18]

Ru Catalyzed Cyclization of Terminal Alkynals to Cycloalkenes
Ru Catalyzed Cyclization of Terminal Alkynals to Cycloalkenes

In this reaction an alkynal 1 is converted into a cycloalkene 7 with a ruthenium catalyst and the actual condensation takes place with intermediate 3 through 5. Support for the reaction mechanism is based on isotope labeling.[b]

The reaction between menthone ((2S,5R)-2-isopropyl-5-methylcyclohexanone) and anisaldehyde (4-methoxybenzaldehyde) is complicated due to steric shielding of the ketone group. This obstacle is overcome by using a strong base such as potassium hydroxide and a very polar solvent such as DMSO in the reaction below:[19]

A Claisen–Schmidt reaction
A Claisen–Schmidt reaction

The product can epimerize by way of a common intermediate—enolate A—to convert between the original (S,R) and the (R,R) epimers. The (R,R) product is insoluble in the reaction solvent whereas the (S,R) is soluble. The precipitation of the (R,R) product drives the epimerization equilibrium reaction to form this as the major product.

Other condensation reactions

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There are other reactions of carbonyl compounds similar to aldol condensation:

See also

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References

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  1. ^ Klein, David R. (December 22, 2020). Organic chemistry (4th ed.). Hoboken, NJ: Wiley. p. 1014. ISBN 978-1-119-65959-4. OCLC 1201694230.
  2. ^ Smith, M. B.; March, J. (2001). Advanced Organic Chemistry (5th ed.). New York: Wiley Interscience. pp. 1218–1223. ISBN 0-471-58589-0.
  3. ^ a b Carey, Francis A.; Sundberg, Richard J. (1993). Advanced Organic Chemistry Part B Reactions and Synthesis (3rd ed.). New York, NY: Plenum. pp. 55. ISBN 0-306-43440-7.
  4. ^ Wade, L. G. (2005). Organic Chemistry (6th ed.). Upper Saddle River, NJ: Prentice Hall. pp. 1056–1066. ISBN 0-13-236731-9.
  5. ^ Mahrwald, R. (2004). Modern Aldol Reactions. Vol. 1, 2. Weinheim, Germany: Wiley-VCH. pp. 1218–1223. ISBN 3-527-30714-1.
  6. ^ Heathcock, C. H. (1991). Additions to C-X π-Bonds, Part 2. Comprehensive Organic Synthesis. Selectivity, Strategy and Efficiency in Modern Organic Chemistry. Vol. 2. Oxford: Pergamon. pp. 133–179. ISBN 0-08-040593-2.
  7. ^ Mukaiyama T. (1982). "The Directed Aldol Reaction". Organic Reactions. 28: 203–331. doi:10.1002/0471264180.or028.03. ISBN 0471264180.
  8. ^ Paterson, I. (1988). "New Asymmetric Aldol Methodology Using Boron Enolates". Chemistry and Industry. 12. London: Paterson Group: 390–394.
  9. ^ Nielsen, A. T.; Houlihan., W. J. (1968). "The Aldol Condensation". Organic Reactions. 16: 1–438. doi:10.1002/0471264180.or016.01. ISBN 0471264180.
  10. ^ Perrin, C. L.; Chang, K. L. (2016). "The Complete Mechanism of an Aldol Condensation". J. Org. Chem. 81 (13): 5631–5. doi:10.1021/acs.joc.6b00959. PMID 27281298.
  11. ^ Carey, Francis A.; Sundberg, Richard J. (1993). Advanced Organic Chemistry Part A: Structure and Mechanisms (3rd ed.). New York, N.Y.: Plenum. pp. 458. ISBN 0-306-43440-7.
  12. ^ Sanyal, S.N. (2003). Reactions, Rearrangements and Reagents (4th ed.). Daryagunj, New Delhi: Bharati Bhavan Publishers (P&D). p. 80. ISBN 978-81-7709-605-7.
  13. ^ Graduated hydrogenation of aldox aldehydes to alcohols US US3118954A 
  14. ^ Schurink, H. B. J. (1925). "Pentaerythritol". Organic Syntheses. 4: 53. doi:10.15227/orgsyn.004.0053; Collected Volumes, vol. 1, p. 425.
  15. ^ Badía, C.; Castro, J. M.; Linares-Palomino, P. J.; Salido, S.; Altarejos, J.; Nogueras, M.; Sánchez, A. (2004). "(E)-6-(2,2,3-Trimethyl-cyclopent-3-enyl)-hex-4-en-3-one". Molbank. 2004 (1): M388. doi:10.3390/M388.
  16. ^ Ethyl 2-methylacetoacetate (2) is added to a stirred solution of sodium hydride in dioxane. Then campholenic aldehyde (1) is added and the mixture refluxed for 15 h. Then 2N hydrochloric acid is added and the mixture extracted with diethyl ether. The combined organic layers are washed with 2N hydrochloric acid, saturated sodium bicarbonate and brine. The organic phase is dried over anhydrous sodium sulfate and the solvent evaporated under reduced pressure to yield a residue that is purified by vacuum distillation to give 3 (58%).
  17. ^ Goren, M. B.; Sokoloski, E. A.; Fales, H. M. (2005). "2-Methyl-(1Z,3E)-butadiene-1,3,4-tricarboxylic Acid, "Isoprenetricarboxylic Acid"". Journal of Organic Chemistry. 70 (18): 7429–7431. doi:10.1021/jo0507892. PMID 16122270.
  18. ^ Varela, J. A.; Gonzalez-Rodriguez, C.; Rubin, S. G.; Castedo, L.; Saa, C. (2006). "Ru-Catalyzed Cyclization of Terminal Alkynals to Cycloalkenes". Journal of the American Chemical Society. 128 (30): 9576–9577. doi:10.1021/ja0610434. PMID 16866480.
  19. ^ Vashchenko, V.; Kutulya, L.; Krivoshey, A. (2007). "Simple and Effective Protocol for Claisen–Schmidt Condensation of Hindered Cyclic Ketones with Aromatic Aldehydes". Synthesis. 2007 (14): 2125–2134. doi:10.1055/s-2007-983746.

Notes

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  1. ^ Heat is usually added manually through the use of a hot plate, or is already present through the use of an exothermic catalyst reaction, such as when -OCH3 is used as the base.

    This drives the second step, by removing water, it allows the reactions equilibrium to continually favor the dehydration mechanism, converting the temporary addition product present to its final condensation product. Otherwise a significant amount of unwanted aldol addition side product would be formed alongside the aldol condensation product.[1]
  2. ^ The ruthenium catalyst, [CpRu(CH3CN)3]PF6, has a cyclopentadienyl ligand, three acetonitrile ligands and a phosphorus hexafluoride counterion; the acidic proton in the solvent (acetic acid) is replaced by deuterium for isotopic labeling. Reaction conditions: 90°C, 24 hrs. 80% chemical yield. The first step is formation of the Transition metal carbene complex 2. Acetic acid adds to this intermediate in a nucleophilic addition to form enolate 3 followed by aldol condensation to 5 at which stage a molecule of carbon monoxide is lost to 6. The final step is reductive elimination to form the cycloalkene.
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