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{{Short description|Pair of chemical reactions}}
{{distinguish|Aldol reaction}}
{{See also|Aldol addition|Aldol condensation}}
{{Reactionbox|Name=Aldol Reactions|Type=|Section3={{Reactionbox Identifiers
{{Reactionbox|Name=Aldol Reactions|Type=|Section3={{Reactionbox Identifiers
| OrganicChemistryNamed =
| OrganicChemistryNamed =
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| Reactant2 = [[Ketone]] or [[Aldehyde]]
| Reactant2 = [[Ketone]] or [[Aldehyde]]
| Reagent1=
| Reagent1=
| Product1 =[[Aldol]]{{br}} or {{br}} [[α,β-Unsaturated carbonyl compound]]
| Product1 =[[Aldol addition|Aldol]]{{br}} or {{br}} [[Aldol condensation|α,β-Unsaturated carbonyl compound]]
| Sideproduct1 =
| Sideproduct1 =
}}|Section1={{Reactionbox Conditions
}}|Section1={{Reactionbox Conditions
| Reference =
| Reference =
| Solvent =
| Solvent =
| Catalyst = {{center|<sup>-</sup>OH or H<sup>+</sup>}}
| Catalyst = {{center|<sup>-</sup>OH or H<sup>+</sup>}}
| Temperature = {{center| Variable<ref>{{Cite book |last=Klein |first=David R. |url=https://www.worldcat.org/oclc/1201694230 |title=Organic chemistry |date=December 22, 2020 |publisher=Wiley |year=2020 |isbn=978-1-119-65959-4 |edition=4th |location=Hoboken, NJ |pages=1014 |oclc=1201694230}}</ref>}}
| Temperature = {{center| Variable<ref>{{Cite book |last=Klein |first=David R. |url=https://www.worldcat.org/oclc/1201694230 |title=Organic chemistry |date=December 22, 2020 |publisher=Wiley |isbn=978-1-119-65959-4 |edition=4th |location=Hoboken, NJ |pages=1014 |oclc=1201694230}}</ref>}}
}}}}In organic chemistry, '''aldol reactions''' are acid- or base-catalyzed reactions of aldehydes or ketones.
}}}}In organic chemistry, '''aldol reactions are acid- or base-catalyzed''' reactions of aldehydes or ketones. '''[[Aldol addition]]''' or '''aldolization''' refers to the addition of an enolate or enolation as a nucleophile to a [[Carbonyl group|carbonyl]] [[Moiety (chemistry)|moiety]] as an electrophile. This produces a β-hydroxyaldehyde or β-hydroxyketone. In an '''[[aldol condensation]]''', water is subsequently eliminated and an α,β-unsaturated carbonyl is formed. The '''aldol cleavage''' or '''Retro-aldol reaction''' is the reverse reaction into the starting compounds.


[[Aldol addition]] or aldolization refers to the addition of an enolate or enolation as a nucleophile to a [[Carbonyl group|carbonyl]] [[Moiety (chemistry)|moiety]] as an electrophile. This produces a β-hydroxyaldehyde or β-hydroxyketone. In an [[aldol condensation]], water is subsequently eliminated and an α,β-unsaturated carbonyl is formed. The '''aldol cleavage''' or '''Retro-aldol reaction''' is the reverse reaction into the starting compounds.
The name ''aldehyde'' -alcohol ''reaction'' derives from the reaction product in the case of a reaction among aldehydes, a [[Aldol|β-hydroxy aldehyde]].


The name ''aldehyde'' -alcohol ''reaction'' derives from the reaction product in the case of a reaction among aldehydes, a [[Aldol|β-hydroxy aldehyde]].
Aldol reactions are important reactions for carbon-carbon bond formation and a fundamental reaction principle in organic chemistry.


Aldol reactions are important reactions for carbon-carbon bond formation and a fundamental reaction principle in organic chemistry.
{{Br|2}}


== Mechanisms ==
== Mechanisms ==
Aldol reactions may proceed by two distinct mechanisms. Carbonyl compounds, such as aldehydes and ketones, can be converted to enols or enol ethers. These species, being nucleophilic at the [[Alpha-carbon|α-carbon]], can attack especially reactive protonated carbonyls such as protonated aldehydes. This is the 'enol mechanism'. Carbonyl compounds, being [[Carbon acid|carbon acids]], can also be deprotonated to form enolates, which are much more nucleophilic than enols or enol ethers and can attack electrophiles directly. The usual electrophile is an aldehyde, since ketones are much less reactive. This is the 'enolate mechanism'.
Aldol reactions may proceed by two distinct mechanisms. Carbonyl compounds, such as aldehydes and ketones, can be converted to enols or enol ethers. These species, being nucleophilic at the [[Alpha-carbon|α-carbon]], can attack especially reactive protonated carbonyls such as protonated aldehydes. This is the 'enol mechanism'. Carbonyl compounds, being [[carbon acid]]s, can also be deprotonated to form enolates, which are much more nucleophilic than enols or enol ethers and can attack electrophiles directly. The usual electrophile is an aldehyde, since ketones are much less reactive. This is the 'enolate mechanism'.


Despite the attractiveness of the aldol manifold, there are several problems that need to be addressed to render the process catalytic and effective. The first problem is a thermodynamic one: most aldol reactions are reversible. Furthermore, the equilibrium is also just barely on the side of the products in the case of simple aldehyde–ketone aldol reactions.<ref>{{Cite book |url=http://www.thieme-connect.de/DOI/DOI?10.1055/b-003-125712 |title=Stereoselective Synthesis 2: Stereoselective Reactions of Carbonyl and Imino Groups |date=2011 |publisher=Georg Thieme Verlag |isbn=978-3-13-154121-5 |editor-last=Molander |editor-first=G. A. |edition=1 |location=Stuttgart |language=en |doi=10.1055/sos-sd-202-00331}}</ref> If the conditions are particularly harsh (e.g.: NaOMe/MeOH/[[reflux]]), condensation may occur. However if an [[Aldol addition]] is desired, this can usually be avoided with mild reagents and low temperatures (e.g., LDA (a strong base), THF, −78&nbsp;°C). Although aldol addition usually proceeds to near completion under irreversible conditions, the isolated aldol adducts are sensitive to base-induced retro-aldol cleavage to return starting materials. In contrast, retro-aldol condensations are rare, but possible.<ref name="Guthrie19842">{{cite journal |author=Guthrie, J.P. |author2=Cooper, K.J. |author3=Cossar, J. |author4=Dawson, B.A. |author5=Taylor, K.F. |year=1984 |title=The retroaldol reaction of cinnamaldehyde |journal=[[Can. J. Chem.]] |volume=62 |issue=8 |pages=1441–1445 |doi=10.1139/v84-243 |doi-access=free}}</ref> This is the basis of the catalytic strategy of class I aldolases in nature, as well as numerous small-molecule amine catalysts.<ref>{{Cite book |url=http://www.thieme-connect.de/products/ebooks/book/10.1055/b-003-125712 |title=Stereoselective Synthesis 2: Stereoselective Reactions of Carbonyl and Imino Groups |date=2011 |publisher=Georg Thieme Verlag |isbn=978-3-13-154121-5 |editor-last=Molander |edition=1 |location=Stuttgart |language=en |doi=10.1055/sos-sd-202-00331}}</ref>
Despite the attractiveness of the aldol manifold, there are several problems that need to be addressed to render the process catalytic and effective. The first problem is a thermodynamic one: most aldol reactions are reversible. Furthermore, the equilibrium is also just barely on the side of the products in the case of simple aldehyde–ketone aldol reactions.<ref>{{Cite book |url=http://www.thieme-connect.de/DOI/DOI?10.1055/b-003-125712 |title=Stereoselective Synthesis 2: Stereoselective Reactions of Carbonyl and Imino Groups |date=2011 |publisher=Georg Thieme Verlag |isbn=978-3-13-154121-5 |editor-last=Molander |editor-first=G. A. |edition=1 |location=Stuttgart |language=en |doi=10.1055/sos-sd-202-00331}}</ref> If the conditions are particularly harsh (e.g.: NaOMe/MeOH/[[reflux]]), condensation may occur. However if an [[Aldol addition]] is desired, this can usually be avoided with mild reagents and low temperatures (e.g., LDA (a strong base), THF, −78&nbsp;°C). Although aldol addition usually proceeds to near completion under irreversible conditions, the isolated aldol adducts are sensitive to base-induced retro-aldol cleavage to return starting materials. In contrast, retro-aldol condensations are rare, but possible.<ref name="Guthrie19842">{{cite journal |author=Guthrie, J.P. |author2=Cooper, K.J. |author3=Cossar, J. |author4=Dawson, B.A. |author5=Taylor, K.F. |year=1984 |title=The retroaldol reaction of cinnamaldehyde |journal=[[Can. J. Chem.]] |volume=62 |issue=8 |pages=1441–1445 |doi=10.1139/v84-243 |doi-access=free}}</ref> This is the basis of the catalytic strategy of class I aldolases in nature, as well as numerous small-molecule amine catalysts.<ref>{{Cite book |url=http://www.thieme-connect.de/products/ebooks/book/10.1055/b-003-125712 |title=Stereoselective Synthesis 2: Stereoselective Reactions of Carbonyl and Imino Groups |date=2011 |publisher=Georg Thieme Verlag |isbn=978-3-13-154121-5 |editor-last=Molander |edition=1 |location=Stuttgart |language=en |doi=10.1055/sos-sd-202-00331}}</ref>
[[File:Simple_aldol_reaction.svg|center|750x750px|A generalized view of the aldol reaction]]
[[File:Simple_aldol_reaction.svg|center|750x750px|A generalized view of the aldol reactions]]


=== Enolate mechanism ===
=== Enolate mechanism ===
If the [[catalyst]] is a moderate base such as [[hydroxide]] ion or an [[alkoxide]], the aldol reaction occurs via nucleophilic attack by the [[Resonance (chemistry)|resonance-stabilized]] enolate on the carbonyl group of another molecule. The product is the [[alkoxide]] salt of the aldol product. Then aldol, the [[aldol addition]] product itself is then formed.
If the [[catalyst]] is a moderate base such as [[hydroxide]] ion or an [[alkoxide]], the aldol reaction occurs via nucleophilic attack by the [[Resonance (chemistry)|resonance-stabilized]] enolate on the carbonyl group of another molecule. The product is the [[alkoxide]] salt of the aldol product. Then aldol, the [[aldol addition]] product itself is then formed.


After which it may undergo dehydration to give a unsaturated carbonyl compound, the [[aldol condensation]] product. The scheme shows a simple mechanism for the base-catalyzed aldol reaction of an aldehyde with itself.
After which it may undergo dehydration to give a unsaturated carbonyl compound, the [[aldol condensation]] product. The scheme shows a simple mechanism for the base-catalyzed aldol reaction of an aldehyde with itself.
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=== Enol mechanism ===
=== Enol mechanism ===
When an acid catalyst is used, the initial step in the [[reaction mechanism]] involves acid-catalyzed [[Tautomer|tautomerization]] of the carbonyl compound to the enol. The acid also serves to activate the carbonyl group of ''another molecule'' by protonation, rendering it highly electrophilic. The enol is nucleophilic at the α-carbon, allowing it to attack the protonated carbonyl compound, leading to the [[Aldol addition|aldol]] after [[deprotonation]].
When an acid catalyst is used, the initial step in the [[reaction mechanism]] involves acid-catalyzed [[tautomer]]ization of the carbonyl compound to the enol. The acid also serves to activate the carbonyl group of ''another molecule'' by protonation, rendering it highly electrophilic. The enol is nucleophilic at the α-carbon, allowing it to attack the protonated carbonyl compound, leading to the [[Aldol addition|aldol]] after [[deprotonation]].


This under the right conditions can then dehydrate to give the unsaturated carbonyl compound, the [[aldol condensation]] product.
This under the right conditions can then dehydrate to give the unsaturated carbonyl compound, the [[aldol condensation]] product.


# '''Acid-catalyzed aldol addition'''[[File:Enol_aldol_formation_mechanism2.svg|center|880x880px|Mechanism for acid-catalyzed aldol reaction of an aldehyde with itself]]
'''Acid-catalyzed aldol mechanism'''
# '''Acid-catalyzed aldol dehydration'''
[[File:Enol_aldol_formation_mechanism2.svg|center|880x880px|Mechanism for acid-catalyzed aldol reaction of an aldehyde with itself]]
'''Acid-catalyzed dehydration'''
[[File:Enol_aldol_dehydration_mechanism2.svg|center|637x637px|Mechanism for acid-catalyzed dehydration of an aldol]]
[[File:Enol_aldol_dehydration_mechanism2.svg|center|637x637px|Mechanism for acid-catalyzed dehydration of an aldol]]


== Intramolecular reaction ==
== Intramolecular reaction ==
[[File:Intramolecular_aldol_reaction_example.svg|thumb|241x241px|'''Fig. 1:''' Mechanism of an intramolecular aldol reaction in basic conditions.{{Br}}Aldol addition product; bottom right{{Br}}Aldol condensation product; top right]]
[[File:Intramolecular_aldol_reaction_example.svg|thumb|241x241px|'''Fig. 1:''' Mechanism of an intramolecular aldol reaction in basic conditions.{{Br}}Aldol addition product; bottom right{{Br}}Aldol condensation product; top right]]
Intramolecular aldol condensation reaction is between two [[aldehyde]] groups or [[ketone]] groups in the same molecule. Five- or six-membered {{math|''α''}}, {{math|''β''}}-unsaturated ketone or aldehydes are formed as products. This reaction is an important approach to the formation of carbon-carbon bonds in organic molecules containing ring systems. As an example, under strong basic conditions (e.g. [[sodium hydroxide]]), [[hexane-2,5-dione]] (compound A in Figure 1) can cyclize via intramolecular aldol reaction to form the 3-methylcyclopent-2-en-1-one (compound B).
Intramolecular aldol condensation is between two [[aldehyde]] groups or [[ketone]] groups in the same molecule. Five- or six-membered {{math|''α''}}, {{math|''β''}}-unsaturated ketone or aldehydes are formed as products. This reaction is an important approach to the formation of carbon-carbon bonds in organic molecules containing ring systems. As an example, under strong basic conditions (e.g. [[sodium hydroxide]]), [[hexane-2,5-dione]] (compound A in Figure 1) can cyclize via intramolecular aldol reaction to form the 3-methylcyclopent-2-en-1-one (compound B).


The mechanism of the intramolecular aldol reaction involves formation of a key [[enolate]] intermediate followed by an intramolecular [[nucleophilic addition]] process. First, hydroxide abstracts the α-hydrogen on a terminal carbon to form the enolate. Next, a [[nucleophilic attack]] of the enolate on the other keto group forms a new carbon-carbon bond (red) between carbons 2 and 6. At last, usually under heating conditions, the elimination of water molecule yields the cyclized α,β-unsaturated ketone.
The mechanism of the intramolecular aldol reaction involves formation of a key [[enolate]] intermediate followed by an intramolecular [[nucleophilic addition]] process.
First, hydroxide abstracts the α-hydrogen on a terminal carbon to form the enolate. Next, a [[nucleophilic attack]] of the enolate on the other keto group forms a new carbon-carbon bond (red) between carbons 2 and 6. This forms the Aldol addition product.
Then, usually under heating conditions, the elimination of water molecule yields the cyclized α,β-unsaturated ketone, the aldol condensation product.
[[File:Intramolecular_aldol_reaction_in_the_total_synthesis_of_Wortmannin.svg|thumb|369x369px|'''Fig. 2:''' Intramolecular aldol reaction in the total synthesis of (+)-Wortmannin.]]
[[File:Intramolecular_aldol_reaction_in_the_total_synthesis_of_Wortmannin.svg|thumb|369x369px|'''Fig. 2:''' Intramolecular aldol reaction in the total synthesis of (+)-Wortmannin.]]
Intramolecular aldol reactions have been widely used in total syntheses of various natural products, especially [[alkaloids]] and [[steroids]]. An example is the application of an intramolecular aldol reaction in the ring closure step for total synthesis of (+)-[[Wortmannin]] by Shigehisa, et al.<ref>Shigehisa, H.; Mizutani, T.; Tosaki, S. Y.; Ohshima, T.; Shibasaki, M, Tetrahedron 2005, 61, 5057-5065.</ref> (Figure 2).
Intramolecular aldol reactions have been widely used in total syntheses of various natural products, especially [[alkaloids]] and [[steroids]]. An example is the application of an intramolecular aldol reaction in the ring closure step for total synthesis of (+)-[[Wortmannin]] by Shigehisa, et al.<ref>Shigehisa, H.; Mizutani, T.; Tosaki, S. Y.; Ohshima, T.; Shibasaki, M, Tetrahedron 2005, 61, 5057-5065.</ref> (Figure 2).
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== References ==
== References ==
{{Reflist}}
{{Reflist}}

[[Category:Organic chemistry]]

Latest revision as of 09:12, 30 April 2024

See also: Aldol addition and Aldol condensation
Aldol Reactions
Reaction
Ketone or Aldehyde
+
Ketone or Aldehyde
Aldol
or
α,β-Unsaturated carbonyl compound
Conditions
Temperature
Variable[1]
Catalyst
-OH or H+

In organic chemistry, aldol reactions are acid- or base-catalyzed reactions of aldehydes or ketones.

Aldol addition or aldolization refers to the addition of an enolate or enolation as a nucleophile to a carbonyl moiety as an electrophile. This produces a β-hydroxyaldehyde or β-hydroxyketone. In an aldol condensation, water is subsequently eliminated and an α,β-unsaturated carbonyl is formed. The aldol cleavage or Retro-aldol reaction is the reverse reaction into the starting compounds.

The name aldehyde -alcohol reaction derives from the reaction product in the case of a reaction among aldehydes, a β-hydroxy aldehyde.

Aldol reactions are important reactions for carbon-carbon bond formation and a fundamental reaction principle in organic chemistry.

Mechanisms

[edit]

Aldol reactions may proceed by two distinct mechanisms. Carbonyl compounds, such as aldehydes and ketones, can be converted to enols or enol ethers. These species, being nucleophilic at the α-carbon, can attack especially reactive protonated carbonyls such as protonated aldehydes. This is the 'enol mechanism'. Carbonyl compounds, being carbon acids, can also be deprotonated to form enolates, which are much more nucleophilic than enols or enol ethers and can attack electrophiles directly. The usual electrophile is an aldehyde, since ketones are much less reactive. This is the 'enolate mechanism'.

Despite the attractiveness of the aldol manifold, there are several problems that need to be addressed to render the process catalytic and effective. The first problem is a thermodynamic one: most aldol reactions are reversible. Furthermore, the equilibrium is also just barely on the side of the products in the case of simple aldehyde–ketone aldol reactions.[2] If the conditions are particularly harsh (e.g.: NaOMe/MeOH/reflux), condensation may occur. However if an Aldol addition is desired, this can usually be avoided with mild reagents and low temperatures (e.g., LDA (a strong base), THF, −78 °C). Although aldol addition usually proceeds to near completion under irreversible conditions, the isolated aldol adducts are sensitive to base-induced retro-aldol cleavage to return starting materials. In contrast, retro-aldol condensations are rare, but possible.[3] This is the basis of the catalytic strategy of class I aldolases in nature, as well as numerous small-molecule amine catalysts.[4]

A generalized view of the aldol reactions
A generalized view of the aldol reactions

Enolate mechanism

[edit]

If the catalyst is a moderate base such as hydroxide ion or an alkoxide, the aldol reaction occurs via nucleophilic attack by the resonance-stabilized enolate on the carbonyl group of another molecule. The product is the alkoxide salt of the aldol product. Then aldol, the aldol addition product itself is then formed.

After which it may undergo dehydration to give a unsaturated carbonyl compound, the aldol condensation product. The scheme shows a simple mechanism for the base-catalyzed aldol reaction of an aldehyde with itself.

Base-catalyzed aldol reaction

Simple mechanism for base-catalyzed aldol reaction of an aldehyde with itself
Simple mechanism for base-catalyzed aldol reaction of an aldehyde with itself

Base-catalyzed dehydration

Simple mechanism for the dehydration of an aldol product
Simple mechanism for the dehydration of an aldol product

Although only a catalytic amount of base is required in some cases, the more usual procedure is to use a stoichiometric amount of a strong base such as LDA or NaHMDS. In this case, enolate formation is irreversible, and the aldol product is not formed until the metal alkoxide of the aldol product is protonated in a separate workup step.

Enol mechanism

[edit]

When an acid catalyst is used, the initial step in the reaction mechanism involves acid-catalyzed tautomerization of the carbonyl compound to the enol. The acid also serves to activate the carbonyl group of another molecule by protonation, rendering it highly electrophilic. The enol is nucleophilic at the α-carbon, allowing it to attack the protonated carbonyl compound, leading to the aldol after deprotonation.

This under the right conditions can then dehydrate to give the unsaturated carbonyl compound, the aldol condensation product.

  1. Acid-catalyzed aldol addition
    Mechanism for acid-catalyzed aldol reaction of an aldehyde with itself
    Mechanism for acid-catalyzed aldol reaction of an aldehyde with itself
  2. Acid-catalyzed aldol dehydration
Mechanism for acid-catalyzed dehydration of an aldol
Mechanism for acid-catalyzed dehydration of an aldol

Intramolecular reaction

[edit]
Fig. 1: Mechanism of an intramolecular aldol reaction in basic conditions.
Aldol addition product; bottom right
Aldol condensation product; top right

Intramolecular aldol condensation is between two aldehyde groups or ketone groups in the same molecule. Five- or six-membered α, β-unsaturated ketone or aldehydes are formed as products. This reaction is an important approach to the formation of carbon-carbon bonds in organic molecules containing ring systems. As an example, under strong basic conditions (e.g. sodium hydroxide), hexane-2,5-dione (compound A in Figure 1) can cyclize via intramolecular aldol reaction to form the 3-methylcyclopent-2-en-1-one (compound B).

The mechanism of the intramolecular aldol reaction involves formation of a key enolate intermediate followed by an intramolecular nucleophilic addition process.

First, hydroxide abstracts the α-hydrogen on a terminal carbon to form the enolate. Next, a nucleophilic attack of the enolate on the other keto group forms a new carbon-carbon bond (red) between carbons 2 and 6. This forms the Aldol addition product.

Then, usually under heating conditions, the elimination of water molecule yields the cyclized α,β-unsaturated ketone, the aldol condensation product.

Fig. 2: Intramolecular aldol reaction in the total synthesis of (+)-Wortmannin.

Intramolecular aldol reactions have been widely used in total syntheses of various natural products, especially alkaloids and steroids. An example is the application of an intramolecular aldol reaction in the ring closure step for total synthesis of (+)-Wortmannin by Shigehisa, et al.[5] (Figure 2).

References

[edit]
  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. ^ Molander, G. A., ed. (2011). Stereoselective Synthesis 2: Stereoselective Reactions of Carbonyl and Imino Groups (1 ed.). Stuttgart: Georg Thieme Verlag. doi:10.1055/sos-sd-202-00331. ISBN 978-3-13-154121-5.
  3. ^ Guthrie, J.P.; Cooper, K.J.; Cossar, J.; Dawson, B.A.; Taylor, K.F. (1984). "The retroaldol reaction of cinnamaldehyde". Can. J. Chem. 62 (8): 1441–1445. doi:10.1139/v84-243.
  4. ^ Molander, ed. (2011). Stereoselective Synthesis 2: Stereoselective Reactions of Carbonyl and Imino Groups (1 ed.). Stuttgart: Georg Thieme Verlag. doi:10.1055/sos-sd-202-00331. ISBN 978-3-13-154121-5.
  5. ^ Shigehisa, H.; Mizutani, T.; Tosaki, S. Y.; Ohshima, T.; Shibasaki, M, Tetrahedron 2005, 61, 5057-5065.
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