Stepwise dansyl grafting on the kaolinite interlayer surface.

Here we describe the step-wise grafting of the fluorophore dansyl chloride on the interlayer aluminol groups of kaolinite. The modified clay was characterized by powder RD, TGA, FT-IR and (27)Al, (19)Si, (13)C MAS-NMR, which confirmed the achievement of the clay functionalization. The photophysical properties of the resulting nanohybrid material were evaluated by photoluminescence excitation and emission measurements.

Substitution reactions between bis-chelate ligands in palladium(II) alkenyl complexes: an unusual way to form unstable trans-P complexes. A study on the isomerization mechanism.

The substitution reactions between asymmetric bis-chelate ligands and alkenyl chloro derivatives of palladium(II) of the type [Pd(L-L')(Rx)Cl] (L-L' = 2-phenylsulfanylmethyl-pyridine (HN-SPh), 2-methyl-6-phenylsulfanylmethyl-pyridine (MeN-SPh), 2,2'-bipyridinyl (BiPy), Rx = -CCOOMe=CMeCOOMe (Ra), -CCOOEt=CMeCOOEt (Rb), -CCOOt-Bu=CMeCOOt-Bu (Rc), -(CCOOMe=CCOOMe)(2)Me (Rd)) with phosphoquinoline moieties (8-diphenylphosphanyl-quinoline (DPPQ), 8-diphenylphosphanyl-2-methyl-quinoline (DPPQ-Me)) usually leads to the formation of the stable geometrical isomer bearing these groups in the cis position thanks to the mutual trans influence of the alkenyl and phosphine groups. However, when the leaving group MeN-SPh and the entering ligand DPPQ are involved, the fast and quantitative substitution reaction leads to the formation of a couple of geometrical isomers [Pd(DPPQ)(Rx)Cl]-trans P and [Pd(DPPQ)(Rx)Cl]-cis P (Rx = Ra, Rb, Rc, Rd) in which the alkenyl and the phosphine groups are in mutual trans or cis position. The substrate [Pd(DPPQ)(Rx)Cl]-trans P (Rx = Ra, Rb, Rc) slowly interconverts into its thermodynamically stable -cis P counterpart while the bulky [Pd(DPPQ)(Rd)Cl]-trans P displays no tendency to isomerize, thereby allowing separation of the two geometrical forms.