S'identifier

15.18 : Dehydration of Aldols to Enones: Acid-Catalyzed Aldol Condensation

The β-hydroxy ketone dehydrates in acidic conditions via an E1 elimination reaction to form an enone.

The E1 elimination proceeds through two distinct steps: ionization and deprotonation.

In the first step, the hydroxyl group in the presence of an acid functions as a Bronsted–Lowry base and accepts a proton to yield a hydrated hydroxyl group. Then, a neutral water molecule departs to give a tertiary carbocation intermediate.

Finally, the chloride ion abstracts the hydrogen atom from the α carbon to form an enone as the product.

As shown in Figure 1, under acidic conditions, the β-hydroxy ketone undergoes dehydration via an E1 elimination reaction to form an enone.

Organic reaction mechanism, dehydration of alcohol to ketone, formula with HCl and H2O.

Figure 1. The dehydration reaction of a β-hydroxy ketone.

Figure 2 depicts the sequential processes involved in the mechanism of the reaction. Here, the acid protonates the hydroxyl group in the β-hydroxy ketone to form a hydrated hydroxyl group, which then departs to form a tertiary carbocation intermediate. Subsequently, the loss of the hydrogen atom from the α carbon yields an enone as the final product.

Ketone formation via alcohol dehydration; chemical reaction diagramc; acid-catalyzed mechanism.

Figure 2. The mechanism of the dehydration reaction of a β-hydroxy ketone.

Tags

Dehydration Aldols Enones Acid catalyzed Aldol Condensation E1 Elimination Reaction hydroxy Ketone Carbocation Intermediate Mechanism Hydroxyl Group Carbon Final Product

Du chapitre 15:

article

Now Playing

15.18 : Dehydration of Aldols to Enones: Acid-Catalyzed Aldol Condensation

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.2K Vues

article

15.1 : Réactivité des énols

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.9K Vues

article

15.2 : Réactivité des ions énolates

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.4K Vues

article

15.3 : Types d’énols et d’énolates

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.5K Vues

article

15.4 : Conventions du mécanisme énologique

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.1K Vues

article

15.5 : Formation régiosélective des énolates

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.5K Vues

article

15.6 : Effets stéréochimiques de l’énolisation

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.0K Vues

article

15.7 : α-halogénation d’aldéhydes et de cétones catalysée par un acide

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.6K Vues

article

15.8 : α-halogénation des aldéhydes et des cétones promue par une base

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.4K Vues

article

15.9 : Halogénation multiple des méthylcétones : réaction haloforme

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.0K Vues

article

15.10 : α-halogénation des dérivés de l’acide carboxylique : aperçu

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.3K Vues

article

15.11 : α-bromation des acides carboxyliques : réaction Hell-Volhard-Zelinski

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.9K Vues

article

15.12 : Réactions des composés α-halocarbonyles : substitution nucléophile

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.2K Vues

article

15.13 : Nitrosation des énols

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.5K Vues

article

15.14 : Formation de liaisons C-C : aperçu de la condensation Aldol

α-Carbon Chemistry: Enols, Enolates, and Enamines

13.5K Vues

See More

Copyright © 2025 MyJoVE Corporation. Tous droits réservés.