Polarity and Dielectric Property Control Triggered by a Coordinated Solvent Molecule Exchange in Luminescent Mononuclear Aluminium(III) Complexes.

The development of molecule-based multifunctional switchable materials that exhibit a switch of polarity and dielectric property are extremely limited. We have demonstrated solvent-vapour-induced reversible molecular rearrangements between nonpolar crystals [Al(sap)(acac)(sol)] (H2 sap=2-salicylideneaminophenol, acac=acetylacetonate, sol=MeOH (1), EtOH (2)) and polar crystal [Al(sap)(acac)(DMSO)] (3). This crystal-to-crystal structural transformation was accompanied by a switch of second harmonic generation (SHG) and dielectric properties, including the formation of ferroelectric domains, thus reflecting the SHG-active polar Cc space group of 3. This is the first reported example of dielectric properties and polarity switching in luminescent mononuclear aluminium(III) complexes, which exhibit strong green emission in the solid state.

Donor-Donor'-Acceptor Triads Based on [3.3]Paracyclophane with a 1,4-Dithiafulvene Donor and a Cyanomethylene Acceptor: Synthesis, Structure, and Electrochemical and Photophysical Properties.

Donor-donor'-acceptor triads (1, 2), based on [3.3]paracyclophane ([3.3]PCP) as a bridge, with electron-donating properties (D') using 1,4-dithiafulvene (DTF; TTF half unit) as a donor and dicyanomethylene (DCM; TCNE half unit) or an ethoxycarbonyl-cyanomethylene (ECM) as an acceptor were designed and synthesized. The pulse radiolysis study of 1 a in 1,2-dichloroethane allowed the clear assignment of the absorption bands of the DTF radical cation (1 a.+ ), whereas the absorption bands due to the DCM radical anion could not be observed by γ-ray radiolysis in 2-methyltetrahydrofuran rigid glass at 77 K. Electrochemical oxidation of 1 a first generates the DTF radical cation (1 a.+ ), the absorption bands of which are in agreement with those observed by a pulse radiolysis study, followed by dication (1 a2+ ). The ESR spectrum of 1 a.+ showed a symmetrical signal with fine structure and an ESR simulation predicted that the spin of 1 a.+ is delocalized over S and C atoms of the DTF moiety and the central C atom of the trimethylene bridge bearing the DTF moiety. Pulse radiolysis, ESR, and electrochemical studies indicate that the DTF radical cation of 1 a.+ is more stable than that of 6.+ , and the latter shows a strong tendency to dimerize. This result indicates that the [3.3]PCP moiety as a bridge can stabilize the DTF radical cation more than the 1,3-diphenylpropane moiety because of kinetic stability due to its rigid structure and the weak electronic interaction of DTF and DCM moieties through [3.3]PCP.

Synthesis, structure and valence-trapping vs. detrapping for new trinuclear iron pentafluoro benzoate complexes: possible recognition of organic molecules by 57Fe Mössbauer spectroscopy.

New mixed-valence trinuclear iron pentafluorobenzoate complexes were synthesized. Their valence-detrapping and/or valence-trapping phenomena were studied by (57)Fe Mössbauer spectroscopy and X-ray crystallography. For [Fe3O(C6F5CO2)6(py)3]·CH2Cl2 (1), a valence-trapped state was observed at low temperatures, while the valence-detrapped state was observed at room temperature. Removal of CH2Cl2 from 1 gives the de-solvated [Fe3O(C6F5CO2)6(py)3] (2) where the valence was trapped at room temperature. The CH2Cl2-free 2 can reversibly absorb and desorb CH3CN; the process was followed by (57)Fe Mössbauer spectroscopy by monitoring valence-trapping and valence-detrapping phenomena. Organic molecules such as benzene, toluene, ethylbenzene, cumene, and xylene are also trapped by 2 and affect the iron valence states. However, small molecules such as H2O and CO2 do not affect the valence-trapped state of 2. Three xylene isomers trapped within the nano-void of 2 were distinguished by (57)Fe Mössbauer spectroscopy at room temperature.

Construction of a photoactive supramolecular system based on a platinum(II) bis-acetylide building block incorporated into a ruthenium(II) polypyridyl complex.

A new ruthenium(ii) polypyridyl-platinum(ii) diethynyl triad containing 3-ethynylphenanthroline linked by platinum(ii) bis-tributylphosphine organometallics, Ru(ii)-Pt(ii)-Ru(ii), and platinum(ii) bis-ethynylphenanthroline complex has been prepared. The ruthenium(ii)-metal triads, Ru(ii)-M-Ru(ii) (M = Pt(ii) and Au(i)), showed typical MLCT absorption bands and a lowest energy pi-pi* absorption involved with the metal perturbation in the 350-500 nm region. Broad emission bands assignable to triplet MLCT transitions were definitely observed in the triads Ru(ii)-M-Ru(ii), while those of platinum(ii) and gold(i) bis-ethynylphenanthroline complexes displayed a phosphorescent band with vibronic progression assignable to the metal-perturbed triplet pi-pi*(C[triple bond]Cphen) transition, which means that the hybrid architecture constructed with Ru(ii) polypyridyl and metal bis-acetylide units converts a blue-green metal perturbed pi-pi* phosphorescence into an orange MLCT-based emission. The transient differential absorption spectra of ruthenium compounds showed the difference of the electron transfer process between [Ru(bipy)(phen)](PF(6))(2) and triads under the MLCT state. Photophysical data of the triad suggest an efficient energy transfer from the platinum bis-acetylide site to the ruthenium polypyridyl site followed by the supposed charge injection from a ruthenium center to the extended pi-conjugated phenanthroline under photo-excitation in this photoactive supramolecular system.

Photophysical properties of ruthenium(II) polypyridyl-gold(I) ethynyl dyads and triads containing mono- or diethynylphenanthroline incorporated into gold(I) triphenylphosphine organometallics.

A new ruthenium(II)-gold(I) dyad, [Ru(bpy)(2){5-{(PPh(3))-Au-C[tripe bond]C}-phen}](PF(6))(2) (2), with a different substituted site compared to [Ru(bpy)(2){3-{(PPh(3))-Au-C[triple bond]C}-phen}](PF(6))(2) (1), and a triad, [Ru(bpy)(2){3,6-bis{(PPh(3))-Au-C[triple bond]C}-phen}](PF(6))(2) (3), with an unsymmetric diethynylphenanthroline relative to [Ru(bpy)(2){3,8-bis{(PPh(3))-Au-C[triple bond]C}-phen}](PF(6))(2) (4) have been prepared. These four ruthenium(II)-gold(I) compounds showed typical metal-to-ligand charge-transfer (MLCT) absorption bands in the 400-550 nm region and a lowest energy pi-pi* absorption involved with the gold(I) perturbation in the 300-400 nm region. Broad emission bands assignable to the triplet MLCT transition were definitely observed in all compounds, indicating that the hybrid architecture constructed with Ru(II)-polypyridyl and Au(I)-ethynyl units converts the blue-green gold(I) perturbed pi-pi* phosphorescence into an orange MLCT-based emission. The transient absorption difference spectra of four compounds showed the difference in the electron transfer process between 2 and other compounds 1, 3, and 4 under the excited state. Ru(II)-Au(I) compounds except for 2 receive the supposed charge injection from a ruthenium center to an extended pi-conjugated ethynyl-substituted phenanthroline, which contains one or two gold(I) organometallic unit(s), while 2 undergoes the electron transfer process from the ruthenium center not to the 5-ethynylphenanthroline but to one of the bipyridyl ligands under the excited state. This hypothesis is supported by the deflection of the spots of 2 and [Ru(bpy)(3)](PF(6))(2) from a linear correlation line in a plot of E(0-0) versus DeltaE(1/2), which was based on the electrochemical and emission data of Ru(II)-Au(I) compounds and mononuclear ruthenium(II) polypyridyl complexes.

Construction of molecular wires based on a gold(I) bis-sigma-acetylide building block incorporated into ruthenium(II) polypyridyl complexes.

An Ru(II)-Au(I)-Ru(II) triad has been synthesized from [Ru(bpy)2(3-ethynylphenanthroline)]2+ with Au(tht)Cl and characterized by spectroscopic means such as NMR and ESI-MS; the Ru(II)-Au(I)-Ru(II) triad shows an intense emission at 620 nm upon excitation at 360 nm, which suggests an efficient energy transfer from the Au site to Ru sites via extended pi-conjugation through the ethynyl units.