ABSTRACT. Analogues of [Ru(bpy) 3 ]2+ were prepared in which one pyridine ligand site is substituted by a N-heterocyclic carbene (NHC) ligand, i.e. either by an imidazolylidene with a variable wingtip group R (R = Me, 3a; R = Et, 3b; R = iPr, 3c), or by a benzimidazolylidene (Me wingtip group, 3d) or by a 1,2,3-triazolylidene (Me wingtip group, 3e). All complexes were characterized spectroscopically, photophysically, and electrochemically. An increase of the size of the wingtip groups from Me to Et or iPr groups distorts the octahedral geometry (NMR spectroscopy) and curtails the reversibility of the ruthenium oxidation. NHC ligands with methyl wingtip groups display reversible ruthenium oxidation at a potential that reflects the donor properties of the NHC ligand (triazolylidene > imidazolylidene > benzimidazolylidene). The most attractive properties were measured for the triazolylidene ruthenium complex 3e, featuring the smallest HOMO-LUMO gap in the series (2.41 eV), a slightly red-shifted absorption profile, and reasonable excited-state lifetime (188 ns) when compared to [Ru(bpy) 3 ] 2+ . These features demonstrate the potential utility of triazolylidene ruthenium complexes as photosensitizers for 2 solar energy conversion.
Chelating ligands
incorporating both N-[1-alkylpyridin-4(1H)-ylidene]amide
(PYA) and N-heterocyclic carbene (NHC) donor sites
were prepared and used for the synthesis of ruthenium(II) complexes.
Cyclic voltammetry, NMR, and UV–vis spectroscopy of the complexes
indicate a solvent-dependent contribution of the limiting resonance
structures associated with the ligand in solution. The neutral pyridylidene
imine structure is more pronounced in apolar solvents (CH2Cl2), while the mesoionic pyridinium amide form is predominant
in polar solvents (MeOH, DMSO). The distinct electronic properties
of these hybrid PYA-NHC ligands in different solvents have a direct
influence on the catalytic activity of the ruthenium center, e.g.,
in the dehydrogenation of benzyl alcohol to benzaldehyde. The activity
in different solvents qualitatively correlates with the solvent permittivity.
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TitleSynthesis, structural, photophysical and electrochemical studies of various d-metal complexes of btp [2,6-bis(1,2,3-triazol-4-yl) [Ru2 2 ]PF 6 Cl, gave rise to the formation a metallosupramolecular gel; the morphology of which was studied using by scanning electron and helium ion microscopy.
Benzimidazolium salts containing both a neutral imine and a masked carboxylate functional group for potential metal chelation were prepared. Palladation of the ester-protected ligand afforded a N,C-bidentate carbene complex 4. Subsequent ester hydrolysis preserved the bidentate coordination mode and yielded complex 5 with a pending COOH group exclusively.However, when ester deprotection was carried out prior to metalation, the N,C,O-tridentate pincer-type coordinated palladium complex 7 was obtained. Proton-abstraction of the dangling COOH group in the bidentate ligand of complex 5 by treatment with a base led to the formation of the N,C,O-tridentate coordinated Pd system 7, and inversely, exposure of the tridentate bound Pd complex 7 with acid afforded the N,C-bidentate ligand coordination mode in complex 5, demonstrating hemilability of the oxygen donor site in the pincer ligand. All three palladium(II) complexes 4, 5, and 7 were evaluated in cross-coupling catalysis and revealed distinct activity differences that are dependent on the type of coupling (Suzuki vs.Heck) and the substrate (Ar-Br vs. Ar-Cl). These differences suggest that judicious choice of donor groups in pincer-type complexes is a viable strategy for catalyst optimization.
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