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Nucleophilic Addition of Hydrazine - The Wolff-Kishner Reaction

A useful variant of the imine-forming reaction just discussed involves the treatment of an aldehyde or ketone with hydrazine, H2N–NH2, in the presence of KOH. Called the Wolff–Kishner reaction, the process is a useful and general method for converting an aldehyde or ketone into an alkane,  R2C=O→.
Nucleophilic Addition of Hydrazine - The Wolff-Kishner Reaction | Chemistry Optional Notes for UPSC

As shown in Figure 19.10, the Wolff–Kishner reaction involves formation of a hydrazone intermediate, R2C═N–, followed by base-catalyzed double-bond migration, loss of Ngas to give a carbanion, and protonation to give the alkane product. The double-bond migration takes place when a base removes one of the weakly acidic NH protons in step 2 to generate a hydrazone anion, which has an allylic resonance structure that places the double bond between nitrogens and the negative charge on carbon. Reprotonation then occurs on carbon to generate the double-bond rearrangement product. The next step—loss of nitrogen and formation of an alkyl anion—is driven by the large thermodynamic stability of the Nmolecule.

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Which reagent is used in the Wolff-Kishner reaction to convert aldehydes or ketones into alkanes?
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Figure 19.10 MECHANISM Mechanism for the Wolff–Kishner reduction of an aldehyde or ketone to yield an alkane.
Nucleophilic Addition of Hydrazine - The Wolff-Kishner Reaction | Chemistry Optional Notes for UPSC

Note that the Wolff–Kishner reduction accomplishes the same overall transformation as the catalytic hydrogenation of an acylbenzene to yield an alkylbenzene. The Wolff–Kishner reduction is more general and more useful than catalytic hydrogenation, however, because it works well with both alkyl and aryl ketones.

The document Nucleophilic Addition of Hydrazine - The Wolff-Kishner Reaction | Chemistry Optional Notes for UPSC is a part of the UPSC Course Chemistry Optional Notes for UPSC.
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FAQs on Nucleophilic Addition of Hydrazine - The Wolff-Kishner Reaction - Chemistry Optional Notes for UPSC

1. What is the Wolff-Kishner reaction?
Ans. The Wolff-Kishner reaction is a chemical transformation that converts a carbonyl compound, such as a ketone or aldehyde, into a corresponding alkane. It involves the use of hydrazine and a strong base under high-temperature conditions to facilitate the nucleophilic addition of hydrazine to the carbonyl group, followed by the elimination of nitrogen gas to form the desired alkane.
2. How does the nucleophilic addition of hydrazine occur in the Wolff-Kishner reaction?
Ans. In the Wolff-Kishner reaction, hydrazine acts as a nucleophile and attacks the electrophilic carbonyl carbon of the ketone or aldehyde. The lone pair of electrons on the nitrogen atom in hydrazine forms a bond with the carbon, resulting in the formation of a new carbon-nitrogen bond. This nucleophilic addition step leads to the formation of a hydrazone intermediate.
3. What is the role of the strong base in the Wolff-Kishner reaction?
Ans. The strong base, typically potassium hydroxide (KOH) or sodium hydroxide (NaOH), is added in the Wolff-Kishner reaction to deprotonate the hydrazone intermediate. This deprotonation step generates a carbanion, which is highly unstable and undergoes intramolecular rearrangement to form a nitrogen gas molecule and an alkane. The strong base also helps to maintain the high temperature required for the reaction.
4. Can the Wolff-Kishner reaction be used to convert other functional groups?
Ans. The Wolff-Kishner reaction is specifically designed for the conversion of carbonyl compounds (ketones and aldehydes) into alkanes. It is not suitable for the conversion of other functional groups. For example, it does not work with carboxylic acids, esters, or amides. Different reactions, such as the Clemmensen reduction or the Barton-McCombie deoxygenation, are employed for the reduction of these functional groups.
5. What are the advantages of using the Wolff-Kishner reaction for carbonyl reduction?
Ans. The Wolff-Kishner reaction offers several advantages for the reduction of carbonyl compounds. It provides a straightforward and efficient method for the synthesis of alkanes from ketones and aldehydes. The reaction conditions are relatively mild compared to other reduction methods, such as the use of metal hydrides. Additionally, the reaction does not require the use of moisture-sensitive reagents, making it more convenient to perform in the laboratory.
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