The challenge of linear (E)-enones in the Rh-catalyzed, asymmetric 1,4-addition reaction of phenylboronic acid: a DFT computational analysis.

Abstract

Why are linear (E)-enones such challenging substrates in the Rh-catalyzed asymmetric arylation with boronic acids, which is one of the most important asymmetric catalysis methods? DFT computations show that these substrates adopt a specific conformation in which the largest substituent is antiperiplanar to Rh(I) π-complexed with the C = C bond within the enantioselectivity-determining carborhodation transition state. Additionally, for such structures, there is a strong, but not exclusive, preference for s-cis enone conformation. This folding minimizes steric interactions between the substrate and the ligand, and hence reduces the enantioselectivity. This idea is further confirmed by investigating three computation-only substrate "probes", one of which is capable of double asymmetric induction, and a recent computationally designed 1,5-diene ligand. On average, excellent agreement between predicted and experimental enantioselectivity was attained by a three-pronged approach: 1) thorough conformational search within ligand and substrate subunits to locate the most preferred carborhodation transition state; 2) including dispersion interaction and long-range corrections by SMD/ωB97xD/DGDZVP level of theory; and 3) full substrate and ligand modeling. Based on the results, a theory-enhanced enantioselectivity model that is applicable to both chiral diene and diphosphane ligands is proposed.