Your search keyword '"C. Morterra"' showing total 9 results

1. 2,6-Dimethylpiridine adsorption on zirconia and sulfated zirconia systems. An FTIR and microcalorimetric study

Author

C. Morterra, Elisabetta Rombi, Giuseppina Meligrana, Vincenzo Solinas, G. Cerrato, and Maria Franca Sini

Subjects

Isothermal microcalorimetry, Materials science, Inorganic chemistry, law.invention, chemistry.chemical_compound, Tetragonal crystal system, Adsorption, law, Desorption, Electrochemistry, ZrO2, General Materials Science, Calcination, Cubic zirconia, adsorption microcalorimetry, Spectroscopy, sulphated ZrO2, 2, 6-dimethylpyridine adsorption, Lewis and Brønsted acidity, FTIR spectroscopy, Surfaces and Interfaces, Condensed Matter Physics, chemistry, Hydroxide, Monoclinic crystal system

Abstract

In situ FTIR spectroscopy and adsorption microcalorimetry have been employed to study the adsorption/desorption of 2,6-dimethylpyridine (2,6-DMP) on different zirconia and sulfated zirconia (SZ) systems. Adsorption/desorption experiments were carried out at 343 K (beam temperature for all IR experiments) and at 423 K. The adsorbents were (i) a (mainly) monoclinic zirconia, (ii) a crystallographically pure tetragonal zirconia, phase stabilized by formation of a solid solution with 3 mol % Y2O3, (iii) monoclinic sulfated zirconia (m-SZ) and tetragonal sulfated zirconia (t-SZ), both noncalcined and calcined at 923 K, obtained by direct sulfation of the two crystalline ZrO2 specimens, and (iv) two t-SZ specimens (also noncalcined and calcined at 923 K), obtained through the “conventional” sulfation procedure carried out on an amorphous hydroxide precursor and leading, upon thermal treatment at T > 823 K, to crystalline t-SZ. The adsorption/desorption of 2,6-DMP turned out to be a valuable probe for both Brons...

Published

2003

2. IR Photothermal Beam Deflection Spectroscopy of Surfaces

Author

C. Morterra, Juan M.D. Tascón, A. G. Severdia, and M. J. D. Low

Subjects

Materials science, business.industry, Optoelectronics, Photothermal microspectroscopy, Photothermal therapy, business, Spectroscopy

Published

1984

3. Catalytic Materials: Relationship Between Structure and Reactivity

Author

THADDEUS E. WHYTE, RALPH A. DALLA BETTA, ERIC G. DEROUANE, R. T. K. BAKER, J. PHILLIPS, J. A. DUMESIC, L. L. LAUDERBACK, W. N. DELGASS, D. G. CASTNER, D. S. SANTILLI, ROBERT J. MADIX, BJERNE S. CLAUSEN, HENRIK TOPSØE, ROBERTO CANDIA, BRUNO LENGELER, B. G. SILBERNAGEL, R. R. MOHAN, G. H. SINGHAL, JANOS B. NAGY, JACK H. LUNSFORD, PAUL G. MEZEY, JULIUS SCHERZER, ALAN W. PETERS, ZELIMIR GABELICA, NIELS BLOM, JACQUES C. VEDRINE, ALINE AUROUX, GISÈLE COUDURIER, D. H. OLSON, W. O. HAAG, C. E. LYMAN, M. J. YACAMAN, J. M. COWLEY, M. M. J. TREACY, HAROLD T. STOKES, E. M. EYRING, S. M. RISEMAN, F. E. MASSOTH, M. J. D. LOW, C. MORTERRA, A. G. SEVERDIA, J. M. D. TASCON, WILLIAM C. KASKA, PAUL K. HANSMA, ATIYE BAYMAN, RICHARD KROEKER, S. ICHIKAWA, H. POPPA, M. BOUDART, THADDEUS E. WHYTE, RALPH A. DALLA BETTA, ERIC G. DEROUANE, R. T. K. BAKER, J. PHILLIPS, J. A. DUMESIC, L. L. LAUDERBACK, W. N. DELGASS, D. G. CASTNER, D. S. SANTILLI, ROBERT J. MADIX, BJERNE S. CLAUSEN, HENRIK TOPSØE, ROBERTO CANDIA, BRUNO LENGELER, B. G. SILBERNAGEL, R. R. MOHAN, G. H. SINGHAL, JANOS B. NAGY, JACK H. LUNSFORD, PAUL G. MEZEY, JULIUS SCHERZER, ALAN W. PETERS, ZELIMIR GABELICA, NIELS BLOM, JACQUES C. VEDRINE, ALINE AUROUX, GISÈLE COUDURIER, D. H. OLSON, W. O. HAAG, C. E. LYMAN, M. J. YACAMAN, J. M. COWLEY, M. M. J. TREACY, HAROLD T. STOKES, E. M. EYRING, S. M. RISEMAN, F. E. MASSOTH, M. J. D. LOW, C. MORTERRA, A. G. SEVERDIA, J. M. D. TASCON, WILLIAM C. KASKA, PAUL K. HANSMA, ATIYE BAYMAN, RICHARD KROEKER, S. ICHIKAWA, H. POPPA, and M. BOUDART

Subjects

Catalysts--Congresses

Published

1984

4. Functionalization of sol gel bioactive glasses carrying Au nanoparticles: selective Au affinity for amino and thiol ligand groups.

Author

Aina V, Marchis T, Laurenti E, Diana E, Lusvardi G, Malavasi G, Menabue L, Cerrato G, and Morterra C

Subjects

Biomimetic Materials chemistry, Cysteine chemistry, Cystine chemistry, Ligands, Spectroscopy, Fourier Transform Infrared, Spectrum Analysis, Raman, Substrate Specificity, Amines chemistry, Glass chemistry, Gold chemistry, Metal Nanoparticles chemistry, Sulfhydryl Compounds chemistry

Abstract

It is demonstrated here that bioactive glasses containing Au nanoparticles (AuNPs) can be selectively functionalized with small molecules carrying either amino or thiol groups by simply varying the temperature and pH of the functionalization batch. The results evidence the following. (i) At room temperature (RT), no functionalization of Au-free glass occurs, whereas in the case of glasses containing AuNPs, stable linkages form only with amino groups, as in this condition Au does not bind with either thiol or hydroxyl groups. The RT functionalization with cysteine and cystine confirms the preferential functionalization through the amino groups, while the -SH groups are oxidized to S-S bridges. (ii) The functionalization with cysteine and cystine, compared at pH = 5, 9, and 12, is shown not to take place at pH = 5 and to be hindered by the glass matrix dissolution at pH = 12 (with consequent release of AuNPs), while the best results are obtained at pH = 9. (iii) For the effect of reaction temperature, at 4 °C it is possible to obtain a strong Au-S interaction, whereas at RT, a weak Au-N linkage is formed. These results should allow production, in a selective way, of different bonds exhibiting different strengths and, consequently, different release times in solution, with a wide range of possible applications (for instance, weak Au-N bonds in the case of drug delivery, strong Au-S bonds in protein immobilization).

Published

2010

5. Bioactive glasses containing Au nanoparticles. Effect of calcination temperature on structure, morphology, and surface properties.

Author

Lusvardi G, Malavasi G, Aina V, Bertinetti L, Cerrato G, Magnacca G, Morterra C, and Menabue L

Subjects

Molecular Structure, Surface Properties, Glass chemistry, Gold, Metal Nanoparticles chemistry, Temperature

Abstract

Bioactive glasses containing gold nanoparticles (AuNPs) have been synthesized via the sol-gel route using HAuCl(4) x 3 H(2)O as gold precursor. The formation process of AuNPs was studied as a function of the thermal treatment, which induces nucleation of Au particles and influences their nature, optical properties, shape, size, and distribution. The physicochemical characterization indicates that the sample treated at 600 degrees C presents the best characteristics to be used as a bioactive material, namely high surface area, high amount of AuNPs located at the glass surface, presence of micropores, and abundant surface OH groups. In the case of samples either aged at 60 degrees C or calcined at 150 degrees C, AuNPs just begin their formation, and at this stage the gel is not completely polymerized and dried yet. A thermal treatment at higher temperatures (900 degrees C) causes the aggregation of AuNPs, forming "AuMPs" (i.e., Au microparticles) in a densified glass-ceramic material with low surface area, absence of pores, and low number of surface OH groups. These features induce in the glass-ceramic materials treated at high-temperatures a lower bioactivity (evidenced by SBF reaction), as compared with that exhibited by the glass samples treated at 600 degrees C.

Published

2010

6. Formation of a nanostructured layer on bioglass particles of different sizes immersed in tris-buffered solution. N2 adsorption and HR-TEM/EDS analysis.

Author

Cerruti M, Perardi A, Cerrato G, and Morterra C

Subjects

Adsorption, Calcium chemistry, Crystallization, Microscopy, Electron, Transmission, Particle Size, Phosphorus chemistry, Silicon Dioxide chemistry, Surface Properties, Biocompatible Materials chemistry, Ceramics chemistry, Nanostructures chemistry, Nitrogen chemistry, Tromethamine chemistry

Abstract

Morphological and structural variations of particles of Bioglass with two different grain sizes reacted in Tris-buffered solution were analyzed by means of N(2) adsorption/desorption at 77 K and HR-TEM/EDS. A remarkable increase in specific surface area (ssa) was observed after the first hour of dissolution. A plateau value corresponding to an increase of at least 2 orders of magnitude was reached after 2 days of dissolution. The ssa increase was faster for the smaller particle size sample, and the ratio between the ssa of the starting samples was not maintained during dissolution. Both micro- and mesopores were formed at different stages of the reaction for the two samples. Increasing ssa was also connected to the formation of a microcrystalline structure rich in Ca and P, as shown by TEM images. The segregation of both a SiO(2)-rich amorphous phase and a Ca/P-rich crystalline phase was observed after the first hour of dissolution. After 2 days of reaction, Ca/P-rich particles made of fine aciculate crystals were found either in close contact with SiO(2) particles or deposited on a small SiO(2)-rich core. A preliminary analysis of TEM data showed the formation, together with hydroxy carbonate apatite, of different types of calcium phosphates not detectable by powder X-ray diffraction.

Published

2005

7. Surface modifications of bioglass immersed in TRIS-buffered solution. A multitechnical spectroscopic study.

Author

Cerruti M, Bianchi CL, Bonino F, Damin A, Perardi A, and Morterra C

Subjects

Hydroxides chemistry, Solutions, Spectrum Analysis, Surface Properties, Ceramics chemistry, Tromethamine

Abstract

Bioglass 45S5 is used in the medical field as a bone regenerative material. In fact, when immersed in body fluid, a layer of hydroxy carbonate apatite (HCA), an analogue to the mineral phase that bones are made of, is deposited on its surface. A mechanism that would explain this process has been hypothesized and includes cation leaching from the glass to the solution and formation of both a silica-rich layer and a Ca/P-rich surface layer, prior to the actual crystallization of HCA. The present paper analyzes the dissolution of 2-mum-size particles of Bioglass in TRIS-buffered solution, focusing on the modifications occurring at the surface of the particles. Results from Transmission FT-IR, Raman, and X-ray Photoelectron Spectroscopy were compared in order to obtain this information. In all cases, precise spectral band assignments were obtained by comparing Bioglass spectra, before and after reaction, with the spectra registered on some selected reference samples. The results confirm the hypothesized mechanism of Bioglass reactivity and yield new insights on the surface modifications of the samples. In particular, the following is shown: the strength of the surface H-bonding system and of water coordination decreases during the reaction; surface carbonates, initially mainly bound to Na, are substituted by an increasing amount of Ca-bound carbonates; and the final calcium phosphate layer obtained is very similar, but not identical, to carbonated hydroxyapatite.

Published

2005

8. The adsorption of C4 unsaturated hydrocarbons on highly dehydrated silica. An IR-spectroscopic and thermodynamic study.

Author

Magnacca G and Morterra C

Abstract

The adsorptive interaction of 1-butyne and 1-butene with a highly dehydrated pyrogenic silica system has been studied to understand the thermodynamic behavior of the adsorption process by the application of the Langmuir model and of the Van't Hoff equation. In situ FTIR spectroscopy allowed the characterization of the adsorption phenomenon in terms of involved surface sites, gas-volumetric determinations yielded quantitative information relative to the adsorption process, and microcalorimetric results allowed the comparison between calculated and experimental data. K(eq) and Delta(ads)G degrees were obtained from Langmuir's model application; Delta(ads)H data were obtained from the Van't Hoff equation and by the isosteric heats method and were compared with experimental values. The virtual constancy of Delta(ads)H with equilibrium pressure and surface coverage (Langmuir model) allowed us to obtain the Delta(ads)H degrees values and, consequently, the Delta(ads)S degrees values for the systems of interest.

Published

2005

9. Carbonate formation on bioactive glasses.

Author

Cerruti M and Morterra C

Subjects

Apatites chemistry, Carbonates chemistry, Glass chemistry, Surface Properties, Apatites chemical synthesis, Calcium Compounds chemistry, Carbonates chemical synthesis, Oxides chemistry, Phosphorus Compounds chemistry, Silicon Dioxide chemistry

Abstract

The system termed 58S is a sol-gel-synthesized bioactive glass composed of SiO2, CaO, and P2O5, used in medicine as bone prosthetic because, when immersed in a physiological fluid, a layer of hydroxycarbonate apatite is formed on its surface. The mechanism of bioactive glass 58S carbonation was studied in the vacuum by means of in-situ FTIR spectroscopy with the use of CO2, H2O, and CD3CN as probe molecules. The study in the vacuum was necessary to identify both the molecules specifically involved in the carbonation process and the type of carbonates formed. Bioactive glass 58S was compared to a Ca-doped silica and to CaO. On CaO, ionic carbonates could form by contact with CO2 alone, whereas on 58S and on Ca-doped silica carbonation occurred only if both CO2 and an excess of H2O were present on the sample. The function of H2O was not only to block surface cationic sites, so that CO2 could not manifest its Lewis base behavior, but also to form a liquid-like (mono)layer that allowed the formation of carbonate ions. The presence of H2O is also supposed to promote Ca2+ migration from the bulk to the surface. Carbonates formed at the surface of CaO and of Ca-bearing silicas (thus including bioactive glasses) are of the same type, but are produced through two different mechanisms. The finding that a water excess is necessary to start heavy carbonation on bioactive glasses seemed to imply that the mechanism leading to in-situ carbonation simulates, in a simplified and easy-to-reproduce system, what happens both in solution, when carbonates are incorporated in the apatite layer, and during sample shelf-aging., (Copyright 2004 American Chemical Society)

Published

2004