Aldol reactions Claisen-Schmidt

Ba.se Catalyzed. Depending on the nature of the hydrocarbon groups attached to the carbonyl, ketones can either undergo self-condensation, or condense with other activated reagents, in the presence of base. Name reactions which describe these conditions include the aldol reaction, the Darzens-Claisen condensation, the Claisen-Schmidt condensation, and the Michael reaction. 

Claisen-Schmidt reaction (Section 18.10) A mixed aldol condensation in which an aromatic aldehyde reacts with an enolizable aldehyde or ketone. 

A different situation is found in the case of crossed aldol reactions, which are also called Claisen-Schmidt reactions. Here the problem arises, that generally a mixture of products might be obtained. 

Benzilic acid rearrangement Benzoin reaction (condensation) Blanc chloromethylation reaction Bouveault-Blanc reduction Bucherer hydantoin synthesis Bucherer reaction Cannizzaro reaction Claisen aldol condensation Claisen condensation Claisen-Schmidt reaction. Clemmensen reduction Darzens glycidic ester condensation Diazoamino-aminoazo rearrangement Dieckmann reaction Diels-Alder reaction Doebner reaction Erlenmeyer azlactone synthesis Fischer indole synthesis. ... 

Crossed aldol condensations, where both aldehydes (or other suitable carbonyl compounds) have a-H atoms, are not normally of any preparative value as a mixture of four different products can result. Crossed aldol reactions can be of synthetic utility, where one aldehyde has no a-H, however, and can thus act only as a carbanion acceptor. An example is the Claisen-Schmidt condensation of aromatic aldehydes (98) with simple aliphatic aldehydes or (usually methyl) ketones in the presence of 10% aqueous KOH (dehydration always takes place subsequent to the initial carbanion addition under these conditions) ... 

The Claisen-Schmidt reaction (Figure 11-17) produces an a,P-unsaturated aldehyde or ketone, the general structure of which is shown in Figure 11-18. The Claisen-Schmidt reaction is a crossed aldol condensation. 

The activated Ba(OH)2 was used as a basic catalyst for the Claisen-Schmidt (CS) condensation of a variety of ketones and aromatic aldehydes (288). The reactions were performed in ethanol as solvent at reflux temperature. Excellent yields of the condensation products were obtained (80-100%) within 1 h in a batch reactor. Reaction rates and yields were generally higher than those reported for alkali metal hydroxides as catalysts. Neither the Cannizaro reaction nor self-aldol condensation of the ketone was observed, a result that was attributed to the catalyst s being more nucleophilic than basic. Thus, better selectivity to the condensation product was observed than in homogeneous catalysis under similar conditions. It was found that the reaction takes place on the catalyst surface, and when the reactants were small ketones, the rate-determining step was found to be the surface reaction, whereas with sterically hindered ketones the adsorption process was rate determining. 

There are numerous examples of both acid- and base-catalyzed mixed aldol condensations involving aromatic aldehydes. The reaction is sometimes referred to as the Claisen-Schmidt condensation. Scheme 2.2 presents some representative examples. 

Reaction between two different aldehydes. In the most general case, this will produce a mixture of four products (eight, if the olefins are counted). However, if one aldehyde does not have an a hydrogen, only two aldols are possible, and in many cases the crossed product is the main one. The crossed aldol reaction is often called the Claisen-Schmidt reaction. 

The intramolecular carbon-carbon bond-forming reactions considered in this section are based on the aldol condensation (see Section 5.18.2, p. 799), the Claisen-Schmidt reaction (see Section 6.12.2, p. 1032), the Claisen ester condensation (see Section 5.14.3, p. 736), and the Claisen reaction (see Section 6.12.2, p. 1032). Since these carbonyl addition reactions are reversible, the methods of synthesis are most successful for the formation of the thermodynamically stable five- and six-membered ring systems. The preparation of the starting materials for some of these cyclisation reactions further illustrates the utility of the Michael reaction (see Section, 5.11.6, p. 681). 

Aldol and related condensation reactions such as Knoevenagel and Claisen-Schmidt condensations are also widely used in the fine chemicals and specialty chemicals, e.g. flavors and fragrances, industries. Activated hydrotalcites have been employed as solid bases in many of these syntheses. Pertinent examples include the aldol condensation of acetone and citral [107, 108], the first step in the synthesis of ionones, and the Claisen-Schmidt condensation of substituted 2-hydroxyacetophenones with substituted benzaldehydes [109], the synthetic... 

The aldol condensation of ketones with aryl aldehydes to form a,p-unsaturated derivatives is called the Claisen-Schmidt reaction ° . ... 

Reaction between Two Different Aldehydes. In the most general case, this will produce a mixture of four products (eight, if the alkenes are counted). However, if one aldehyde does not have an a hydrogen, only two aldols are possible, and in many cases the crossed product is the main one. The crossed-aldol reaction is often called the Claisen-Schmidt reaction. The crossed aldol is readily accomplished using amide bases in aprotic solvent. The first aldehyde is treated with LDA in THF at —78°C, for example, to form the enolate anion. Subsequent treatment with a second aldehyde leads to the mixed aldol product. The crossed aldol of two aldehydes has been done using potassium ferf-butoxide and Ti(OBu)4. ... 

The reaction of an aldehyde with a ketone employing sodium hydroxide as the base is an example of a mixed aldol condensation reaction, the Claisen-Schmidt reaction. Dibenzalacetone is readily prepared by condensation of acetone with two equivalents of benzaldehyde. The aldehyde carbonyl is more reactive than that of the ketone and therefore reacts rapidly with the anion of the ketone to give a /3-hydroxyketone, which easily undergoes base-catalyzed dehydration. Depending on the relative quantities of the reactants, the reaction can give either mono- or dibenzalacetone. 

The Claisen-Schmidt Reaction. When aromatic aldehydes are treated with aliphatic ketones in the presence of base, three reactions might be expected a Cannizzaro reaction of the aromatic aldehyde an aldol-type reaction of the ketone or a crossed aldol reaction between the ketone and the aromatic aldehyde. In either of the last two possibilities dehydration might also occur. Undoubtedly all these reactions will take place in strong base, but by employing about 10 per cent aqueous sodium hydroxide, good yields are often obtained of j3-unsaturated carbonyl conipounds derived from a crossed aldol reaction between the aldehyde and the ketone. This reaction, generally called a Claisen-Schmidt reaction, can be illustrated by the synthesis of benzalacetophenone.16... 

The trivial name of the reaction was applied by Wurtz in 1872, and stems from the trivial name of the dimer resulting from the acid-catalyzed self-reaction of acetaldehyde (equation 1). In time, the term came to be applied to the analogous self-condensation reactions of ketones, the first known example of which was the acid-mediated dimerization of acetone, discovered in 1838. The first use of a base as a catalyst for the aldol reaction was in the reaction of furfural with acetaldehyde or acetone (equation 2). This example also illustrates the first example of a mixed aldol reaction, a process that came to be known as the Claisen-Schmidt condensation. ... 

Aldol addition and condensation reactions involving two different carbonyl compounds are called mixed aldol reactions. To be useful as a method for synthesis there must be some basis for controlling which carbonyl component serves as the electrophile and which acts as the enolate precursor. One of the most general mixed aldol condensations involves the use of aromatic aldehydes with alkyl ketones or aldehydes. There are numerous examples of both acid- and base-catalyzed mixed aldol condensations involving aromatic aldehydes. The reaction is sometimes referred to as the Claisen-Schmidt condensation. Aromatic aldehydes are incapable of enolization and cannot function as the nucleophilic component. Furthermore, dehydration is especially favorable because the resulting enone is conjugated with the aromatic ring. 

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