6533b852fe1ef96bd12aa432

RESEARCH PRODUCT

A theoretical study on NHC-catalysed enantioselective cycloaddition of ketenes and 3-aroylcoumarins: mechanism and enantioselectivity.

Ramón J. ZaragozáMaría José AurellMiguel A. González-cardenete

subject

Enantioselective010405 organic chemistryStereochemistryOrganic ChemistryEnantioselective synthesisKeteneCarbene010402 general chemistryDFT01 natural sciencesBiochemistryTransition stateCycloaddition0104 chemical sciencesAdductchemistry.chemical_compoundKetenechemistryNucleophileIntramolecular forceAroylcoumarinPhysical and Theoretical ChemistryCarbene

description

NHC-catalysed enantioselective cycloaddition of ketenes to 3-aroylcoumarins to yield dihydrocoumarin-fused dihydropyranones has been investigated using DFT methods at the B3LYP/6-31G* and MPWB1K/6-311G** computational levels. Two plausible mechanisms have been studied: the “ketene-first” mechanism A and the “coumarin-first” mechanism B. An analysis of the activation Gibbs free energies involved in the two competitive pathways makes it possible to rule out the pathway associated with the “coumarin-first” mechanism B. The first step of the “ketene-first” mechanism A is the formation of zwitterionic intermediate IN1-Zvia a nucleophilic attack of NHC 1 on ketene 2. A [4 + 2] cycloaddition through the nucleophilic attack of enolate IN1-Z on the conjugated double bond of the benzoyl group of coumarin 3, viaTS3-SS-a2 or TS3-RR-a2, yields IN3. Finally, the extrusion of the catalyst through TS5 leads to the final products, either 4-SS or 4-RR. Enantioselectivity observed in the experimental results is determined in the transition states TS3-SS-a2/TS3-RR-a2. In this pathway, the intramolecular hydrogen-bonding between the hydroxyl group of the IN1-Z adduct and the carbonyl oxygen of the original ketene group directs the final stereochemistry throughout the entire process.

10.1039/c8ob01035hhttps://pubmed.ncbi.nlm.nih.gov/30022178