Baylis–Hillman reaction: Difference between revisions
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File:MBH general scheme.png|MBH general scheme | |||
File:MBH initial mechanism.png|MBH initial mechanism | |||
File:MBH revised mechanism.png|MBH revised mechanism | |||
File:MBH Scope Diagram.png|MBH Scope Diagram | |||
File:MBHexample.png|MBH example | |||
File:Double MBH rxn.png|Double MBH reaction | |||
File:Sila MBH reaction.png|Sila MBH reaction | |||
File:Intramolecular RC reaction.png|Intramolecular RC reaction | |||
File:3-component MBH.png|3-component MBH | |||
File:Tandem MBH cyclization.png|Tandem MBH cyclization | |||
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Latest revision as of 05:59, 3 March 2025
Baylis–Hillman Reaction
The Baylis–Hillman reaction is a chemical reaction that involves the coupling of an aldehyde or ketone with an activated alkene in the presence of a catalyst, typically a tertiary amine such as DABCO (1,4-Diazabicyclo[2.2.2]octane) or a phosphine. This reaction is an important tool in organic chemistry for the formation of carbon-carbon bonds, leading to the production of α-methylene-β-hydroxy esters, amides, or nitriles. It was independently discovered by Anthony B. Baylis and Melville E. D. Hillman in the 1970s.
Mechanism[edit]
The Baylis–Hillman reaction mechanism is complex and involves several steps. Initially, the catalyst activates the aldehyde or ketone through the formation of an adduct. This activation increases the electrophilicity of the carbonyl carbon, facilitating its nucleophilic attack by the activated alkene. The key intermediate formed is an alkoxide, which upon protonation yields the final product, a α-methylene-β-hydroxy compound. The reaction mechanism is highly dependent on the nature of the catalyst and the substrates involved.
Applications[edit]
The Baylis–Hillman reaction has found widespread applications in the synthesis of complex organic molecules, including natural products and pharmaceuticals. Its ability to efficiently construct carbon-carbon bonds makes it a valuable tool for the synthesis of chiral compounds, polymers, and materials science. The reaction's versatility and mild conditions have also made it a staple in combinatorial chemistry for the generation of diverse molecular libraries.
Variants[edit]
Several variants of the Baylis–Hillman reaction have been developed to expand its scope and efficiency. These include:
- The Aza-Baylis–Hillman reaction, which involves the use of imines instead of aldehydes or ketones, leading to the formation of α-methylene-β-amino compounds.
- The Morita–Baylis–Hillman reaction, which employs phosphine catalysts and is particularly useful for the synthesis of α-methylene-β-hydroxy phosphonates.
- The use of chiral catalysts for the enantioselective synthesis of chiral centers via the Baylis–Hillman reaction.
Challenges and Solutions[edit]
Despite its utility, the Baylis–Hillman reaction can be challenging due to slow reaction rates and the potential for side reactions. Various strategies have been employed to overcome these challenges, including the use of modified catalysts, solvent effects, and ultrasonic irradiation to enhance reaction rates and selectivity.
Conclusion[edit]
The Baylis–Hillman reaction represents a powerful method for the construction of complex organic molecules. Its versatility and the development of numerous variants have made it an indispensable tool in the arsenal of synthetic organic chemists.
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MBH general scheme -
MBH initial mechanism -
MBH revised mechanism -
MBH Scope Diagram -
MBH example -
Double MBH reaction -
Sila MBH reaction -
Intramolecular RC reaction -
3-component MBH -
Tandem MBH cyclization
