Free-standing cellulose film containing manganese dioxide nanoparticles and its use in discoloration of indigo carmine dye.

In this study, we report the production of a free-standing film of non-modified cellulose impregnated with 12 wt.% of MnO2 nanoparticles with less than 100 nm in size. The method here described can be applied to the immobilization of different types of nanoparticles. The film was prepared by dissolving microcrystalline cellulose in an ionic liquid followed by its regeneration by adding water to the former solution. Then, the wet film was impregnated with the nanoparticles by dipping it in a MnO2 dispersion. Electron microscopy images revealed manganese dioxide nanoparticles distributed not only at the film surface but also in its interior. The cellulose film impregnated with MnO2 nanoparticles was capable of efficiently discolouring an Indigo Carmine dye solution in 25 min upon ambient light. The film was easily removed from the dye solution and repeatedly reused for at least 10 times without losing its discolouring efficiency.

Production of self-supported conductive films based on cellulose, polyaniline and silver nanoparticles.

Synthetic efforts are being made to produce electrical conductive films based on a combination of cellulose matrix with conducting polymers. Improved mechanical properties and processability of the conducting polymers can be attained by promoting this combination, allowing the production of electrical conductive membranes or sheet of paper-like forms that have many technological uses. Cellulose films containing different amounts of polyaniline combined to silver nanoparticles were prepared in homogenous conditions by the dissolution of microcrystalline cellulose in 1-butyl-3-methylimidazolium chloride ionic liquid, followed by the mixing with dispersion of silver nanoparticles and polyaniline also prepared in an ionic liquid. Films with high electrical conductivities (23-34 S·cm-1) and homogeneous distribution of the constituents were produced. The high conductivity was promoted by the presence of polyaniline in its most conductivity state with the silver nanoparticles affording the electrical contact among these chains creating a conductive network spread throughout the insulating cellulose matrix.

Structure of tetraalkylammonium ionic liquids in the interlayer of modified montmorillonite.

We perform molecular dynamics simulations of tetraalkylammonium ionic liquids confined in the interlayer of montmorillonite (MMT). We study the structure and energetics of the systems, which consist of cations with two different alkyl chain lengths and several ionic liquid concentrations. The results we obtained for the structure, namely the presence of a strong layering in all systems and the formation of nonpolar domains with interdigitated alkyl chains in some cases, are largely consistent with previous surface force balance experiments performed on similar systems. Finally, we show that swelling of the organo-modified MMT by a large amount of ionic liquid seems energetically favorable in all cases.

Evaluation of hexaniobate nanoscrolls as support for immobilization of a copper complex catalyst.

In this work, we report the intercalation properties of the hexaniobate nanoscrolls toward insertion of 2-[2-(2-pyridyl)ethylimino-1-ethyl]pyridine-imidazole copper(II), [Cu(apip)imH]2+, a cationic complex able to promote the catalytic oxidation of organic substrates. Hexaniobate was first transformed into its acidic phase, H2K2Nb6O17, and then exfoliated with n-butylamine in water. The copper complex was immobilized into the nanoscrolls obtained by the acidification of delaminated particle dispersion at pH 3. TEM micrographs of particles after immobilization of the cationic complex show scrolls with external diameters of ca. 25-30 nm and wall thicknesses of about 4.5-7.0 nm. The basal spacing (d(040)) of the copper complex intercalated in hexaniobate is about 11.6 A. The estimated composition, [Cu(apip)imH](0.5)HK2Nb6O17.6H2O, indicates that 50% of the negative charge of interlayer I was neutralized by the copper complex. EPR and IR spectra showed that the ligands and the distorted tetragonal structure of the complex were maintained after immobilization into niobate. The reactivity of this new material toward catechol oxidation using hydrogen peroxide as the oxidizing agent was investigated and compared to the activity of the same complex in solution. The heterogeneous catalyst is initially less effective toward the catechol oxidation but with time, the reaction shows a higher catechol conversion (ca. 82%) than the same copper complex in homogeneous media (ca. 75%). A better reactivity of the heterogeneous catalyst may be related to the stabilization of the immobilized catalyst, preventing its degradation during the reaction course. EPR results show that the kinetics of formation of the DMPO/*OH adduct in homogeneous and heterogeneous conditions corresponds to that observed in the catechol oxidation, suggesting that hydroxyl radicals are involved in the reaction mechanism.

Intercalation compounds involving inorganic

Two-dimensional inorganic networks can shown intracrystalline reactivity, i.e., simple ions, large species as Keggin ions, organic species, coordination compounds or organometallics can be incorporated in the interlayer region. The host-guest interaction usually causes changes in their chemical, catalytic, electronic and optical properties. The isolation of materials with interesting properties and making use of soft chemistry routes have given rise the possibility of industrial and technological applications of these compounds. We have been using several synthetic approaches to intercalate porphyrins and phthalocyanines into inorganic materials: smectite clays, layered double hydroxides and layered niobates. The isolated materials have been characterized by elemental and thermal analysis, X-ray diffraction, surface area measurements, scanning electronic microscopy, electronic and resonance Raman spectroscopies and EPR. The degree of layer stacking and the charge density of the matrices as well their acid-base nature were considered in our studies on the interaction between the macrocycles and inorganic hosts.