JappâKlingemann reaction | |
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Named after |
Francis Robert Japp Felix Klingemann |
Reaction type | Coupling reaction |
Identifiers | |
RSC ontology ID | RXNO:0000158 |
The JappâKlingemann reaction is a chemical reaction used to synthesize hydrazones from β-keto-acids (or β-keto-esters) and aryl diazonium salts. [1] [2] [3] [4] [5] [6] The reaction is named after the chemists Francis Robert Japp and Felix Klingemann.
The hydrazone products of the JappâKlingemann reaction are most often used as intermediates in syntheses of more complex organic molecules. For example, a phenylhydrazone product can be heated in the presence of strong acid to produce an indole via the Fischer indole synthesis. [7] [8]
If there is a leaving group elsewhere in the JappâKlingemann product, the hydrazone instead can cyclize at that site via a substitution reaction to give a pyrazole. This process is a key part of the synthesis of pyraclofos and related compounds: [9]
To illustrate the mechanism, the Japp-Klingemann ester variation will be considered. The first step is the deprotonation of the β-keto-ester. The nucleophilic addition of the enolate anion 2 to the diazonium salt produces the azo compound 3. Intermediate 3 has been isolated in rare cases. However, in most cases, the hydrolysis of intermediate 3 produces a tetrahedral intermediate 4, which quickly decomposes to release the carboxylic acid 6. After hydrogen exchange, the final hydrazone 7 is produced.
JappâKlingemann reaction | |
---|---|
Named after |
Francis Robert Japp Felix Klingemann |
Reaction type | Coupling reaction |
Identifiers | |
RSC ontology ID | RXNO:0000158 |
The JappâKlingemann reaction is a chemical reaction used to synthesize hydrazones from β-keto-acids (or β-keto-esters) and aryl diazonium salts. [1] [2] [3] [4] [5] [6] The reaction is named after the chemists Francis Robert Japp and Felix Klingemann.
The hydrazone products of the JappâKlingemann reaction are most often used as intermediates in syntheses of more complex organic molecules. For example, a phenylhydrazone product can be heated in the presence of strong acid to produce an indole via the Fischer indole synthesis. [7] [8]
If there is a leaving group elsewhere in the JappâKlingemann product, the hydrazone instead can cyclize at that site via a substitution reaction to give a pyrazole. This process is a key part of the synthesis of pyraclofos and related compounds: [9]
To illustrate the mechanism, the Japp-Klingemann ester variation will be considered. The first step is the deprotonation of the β-keto-ester. The nucleophilic addition of the enolate anion 2 to the diazonium salt produces the azo compound 3. Intermediate 3 has been isolated in rare cases. However, in most cases, the hydrolysis of intermediate 3 produces a tetrahedral intermediate 4, which quickly decomposes to release the carboxylic acid 6. After hydrogen exchange, the final hydrazone 7 is produced.