Organocatalysis for Enantioselective Decarboxylative Nucleophilic Addition Reactions

Abstract

AbstractThe catalytic decarboxylation of malonic acid half oxy‐ and thioesters, β‐ketocarboxylic acids, and their related compounds is a straightforward, powerful, and atom‐economical strategy for the in‐situ formation of enolates, which are important and well‐studied synthons for various functional materials and natural products. This strategy, inspired by the biosynthesis of polyketides and fatty acids, is an attractive method for synthesizing enols from carboxyl compounds with less reactive α‐hydrogen atoms under mild conditions. In addition, these reactions are environmentally friendly and are of great interest to chemists because the use of a stoichiometric amount of base can be avoided, and the only byproduct is CO2. Thus far, remarkable progress has been made, especially in the field of organocatalytic enantioselective decarboxylation reactions, allowing for the stereocontrolled formation of new C−H, C−C, C−heteroatom, and C−X bonds. This review provides a comprehensive overview of organocatalytic enantioselective decarboxylation reactions and highlights the significant progress made since 2020. In particular, it focuses on chiral catalyst systems and transition states as key parameters for decarboxylation reactions.