Stereolability of Chiral Ruthenium Catalysts With Frozen NHC Ligand Conformations Investigated by Dynamic‐HPLC

The stereolability of chiral Hoveyda–Grubbs II type ruthenium complexes bearing N‐heterocyclic carbene (NHC) ligands with Syn‐phenyl groups on the backbone and Syn‐ or Anti‐oriented o‐tolyl N‐substituents was studied by resorting to dynamic high‐performance liquid chromatography (D‐HPLC). A complete chromatographic picture of the involved stereoisomers (four for Anti‐ and two for Syn‐complexes) was achieved at very low temperatures (?53°C and ?40°C respectively), at which the NHC‐Ru bond rotations were frozen out. Inspection of the chromatographic profiles recorded at higher temperatures revealed the presence of plateau zones between the couples of either Syn or Anti stereoisomers, attesting to the active interconversion between the eluted species. Such dynamic chromatograms were successfully simulated through procedures based on both theoretical plate and classical stochastic models. The good superimposition achieved between experimental and simulated chromatographic profiles allowed determination of the related isomerization energy barriers (ΔG_isom^#), all derived by rotation around the NHC‐Ru bond. The obtained diastereomerization barriers between the Anti isomers were found in very good agreement with those previously measured by experimental nuclear magnetic resonance (NMR) and assessed through Density Functional Theory (DFT) calculations. With the same approach, for the first time we also determined the enantiomerization barrier of the Syn isomer. Focused changes to the structure of complex Syn, studied by a molecular modeling approach, were found suitable to strongly reduce the stereolability arising from rotation around the NHC‐Ru bond. Chirality 27:685–692, 2015. © 2015 Wiley Periodicals, Inc.