Litcius/Paper detail

Catalytic Asymmetric <i>P</i>-Site Dearomatization Enables Kinetic Resolution

Dongwei Zhao, Junjie Sun, Ning Chen, Yicong Ge, Jingjing Liu, Lu Bai, Xinjun Luan

2025Journal of the American Chemical Society15 citationsDOI

Abstract

Dearomatization of planar aromatics offers unparalleled opportunities for the construction of three-dimensional stereochemical frameworks. However, the inherent instability of dearomatized intermediates, particularly bearing labile C(sp 3 )–heteroatom bonds, has hindered progress due to competing rearomatization pathways. By capitalizing on arene dearomatization and transforming the rearomatization predicament into a new opportunity, we herein present a stability-driven catalytic asymmetric dearomatization/rearomatization (CADA/RA) cooperative strategy to resolve racemic P -stereogenic compounds. Through the systematic engineering of phenolic substrates, bench-stable P -site dearomatized products with dual C(sp 3 )–P and C(sp 3 )–Cl bonds were isolated. Chiral Lewis acid catalysis enabled kinetic resolution (KR) and parallel kinetic resolution (PKR), achieving full enantiomeric separation with exceptional stereocontrol across diverse substrates. Mechanistic analysis revealed competing substrate- and catalyst-controlled pathways for stereochemical precision. Postsynthetic chemoselective Cl - or P -liberation furnished enantioenriched P -chiral compounds. This method transforms the challenges of dearomatization and rearomatization into opportunities for stereochemical complexity generation, offering a robust platform to synthesize P -chiral building blocks and ligand precursors.

Topics & Concepts

ChemistryStereocenterKinetic resolutionCatalysisHeteroatomEnantiomerLigand (biochemistry)Enantioselective synthesisSubstrate (aquarium)Lewis acids and basesPhosphineStereochemistryCombinatorial chemistryIntramolecular forceOrganic chemistryRing (chemistry)ReceptorOceanographyBiochemistryGeologyAsymmetric Hydrogenation and CatalysisAsymmetric Synthesis and CatalysisSynthetic Organic Chemistry Methods
Catalytic Asymmetric <i>P</i>-Site Dearomatization Enables Kinetic Resolution | Litcius