The catalytic activity of ruthenium Hoveyda–Grubbs
complexes
in olefin metathesis is a function of complex steric and electronic
effects acting on initiation and propagation steps. In order to study
the π-electron factors influencing the initiation process, we
attempted syntheses of bimetallic complexes with common organic ligands
bearing two chelate rings. While most of the studied ligand exchange
reactions of the isomeric bis-chelating benzene derivatives gave mixtures
of unstable complexes, a homodinuclear derivative of 1,4-dimethoxy-2,5-divinylbenzene
was sparingly soluble and precipitated from the reaction mixture in
a pure form. The complex was studied with spectroscopic and X-ray
methods, which confirmed the symmetrical bimetallic structure. However,
in model metathesis reactions the catalyst displayed activity very
comparable to the related monometallic complexes. This suggests that
in the bimetallic system two consecutive initiation processes of the
metathesis catalyst (first, bimetallic complex + olefin → monometallic
complex + propagating species; second, monometallic complex + olefin
→ styrene + propagating species) proceed at similar rates and,
thus, no cooperativity between the two steps is displayed. Properties
of the family of bimetallic complexes were probed with NMR studies,
and π-electronic effects operating in the systems were discussed.
Derivatives of the Hoveyda-Grubbs complex bearing S-, Br-, I-, and N-coordinating naphthalene ligands were synthesized and characterized with NMR and X-ray studies. Depending on the arrangement of the coordinating sites on the naphthalene core, the isomeric catalysts differ in activity in model metathesis reactions. In particular, complexes with the RuCH bond adjacent to the second aromatic ring of the ligand suffer from difficulties experienced on their preparation and initiation. The behavior most probably derives from steric hindrance around the double bond and repulsive intraligand interactions, which result in abnormal chemical shifts of benzylidene protons observed with (1) H NMR. Furthermore EXSY studies revealed that the halogen-chelated ruthenium complexes display an equilibrium, in which major cis-Cl2 structures are accompanied with small amounts of isomeric forms. In general, contents of the minor forms, measured at 80 °C, correlate with the observed activity trends of the catalysts, although some exceptions complicate the mechanistic picture. We assume that for the family of halogen-chelated metathesis catalysts the initiation mechanism starts with the cis-Cl2 ⇌trans-Cl2 isomerization, although further steps may become rate-limiting for selected systems.
Molecular scaffolds of polycyclic aromatic hydrocarbons can serve as unique tools to control the molecular and electronic structure of coordination compounds. Herein, we report the synthesis and properties of a Hoveyda−Grubbs metathesis catalyst bearing a chelating benzylidene ligand assembled on peri-substituted naphthalene. In contrast to other reported naphthalene-based complexes (Barbasiewicz, M.; Grela, K. et al. Chem. Eur. J. 2008, 14, 9330−9337), it exhibits a very fast initiation behavior, attributed to a distorted molecular structure and reduced π-electron delocalization within the chelate ring.
N-Aryl-2-nitrosoanilines, easily available from reaction of nitroarenes with anilide anions, undergo base-promoted condensation reaction with substituted benzyl aryl sulfones, furnishing 1,2-diaryl-1H-benzimidazoles.
We have synthesized a series of N-phenylpyrrole and N-phenylindole carbenes and used them as ruthenium-ligating moieties in the synthesis of Hoveyda-Grubbs catalyst derivatives. We show that most of these complexes are difficult to synthesize and unstable apart from the N-phenylpyrrole-2,6-diisopropylphenyl ruthenium complex and its perbrominated derivative. These two systems are almost completely inactive in ring-closing metathesis at room temperature and become active only at 80 °C. DFT, SAPT0 and DLPNO-CCSD(T) calculations suggest that the rarely occurring phenyl-ruthenium interactions are responsible for the very slow initiation of these precatalysts at low temperatures.
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