Your search keyword '"Chiodelli G."' showing total 4 results

1. Jahn-Teller effect in in Al3+-doped LiMn2O4 spinel

Author

Capsoni D. 1, Bini M. 2, Chiodelli G. 1, Mustarelli P. 1, Massarotti V. 1, Azzoni C.B. 3, Mozzati M.C. 3, and Linati L. 2

Subjects

Spinels, Jahn-Teller, EPR, Gas sensors, NMR

Published

2003

2. Structural transition in Mg-doped LiMn2O4: a comparison with other ions doping

Author

Capsoni D. 1, Bini M. 2, Chiodelli G. 1, Massarotti V. 1, Mozzati M.C. 3, and Azzoni C.B. 3

Subjects

Lithium batteries, Cathodic material, EPR, X-ray scattering, Phase transition

Published

2003

3. Role of doping and CuO segregation in improving the giant permittivity of CaCu3Ti4O12

Author

Capsoni, D., Bini, M., Massarotti, V., Chiodelli, G., Mozzatic, M.C., and Azzoni, C.B.

Subjects

*PEROVSKITE, *OXIDE minerals, *CRYSTAL growth, *DISLOCATIONS in crystals

Abstract

Abstract: The dopant role on the electric and dielectric properties of the perovskite-type CaCu3Ti4O12 (CCTO) compound is evidenced. Impedance spectroscopy measurements show that the relevant permittivity value attributed to sintered CCTO is due to grain boundary (g.b.) effects. The g.b. permittivity value of the pure CCTO can be increased of 1–2 orders of magnitude by cation substitution on Ti site and/or segregation of CuO phase, while the bulk permittivity keeps values . Bulk and g.b. conductivity contributions are discussed: electrons are responsible for the charge transport and a mean bulk activation energy of 0.07eV is obtained at room temperature for all the examined samples. The g.b. activation energy ranges between 0.54 and 0.76eV. Defect models related to the transport properties are proposed, supported by electron paramagnetic resonance measurements. [Copyright &y& Elsevier]

Published

2004

4. Cations distribution and valence states in Mn-substituted Li4Ti5O12 structure

Author

Gaetano Chiodelli, Vincenzo Massarotti, Marcella Bini, Laura Linati, Stefania Ferrari, Doretta Capsoni, Piercarlo Mustarelli, Maria Cristina Mozzati, Carlo B. Azzoni, Capsoni, D, Bini, M, Massarotti, V, Mustarelli, P, Chiodelli, G, Azzoni, C, Mozzati, M, Linati, L, and Ferrari, S

Subjects

Valence (chemistry), valenza dei cationi, Chemistry, General Chemical Engineering, Li4Ti5O12, Analytical chemistry, General Chemistry, Distribuzione Cationica, NMR, law.invention, Ion, NMR spectra database, Paramagnetism, Lattice constant, Octahedron, law, materiale catodico, Materials Chemistry, EPR, Raggi X, Electron paramagnetic resonance, Drogaggio, Sintesi, Powder diffraction

Abstract

Structure, cation distribution, Mn oxidation states, and conductivity behavior of the Mn-substituted (up to 30% of Ti ions) Li4Ti5O12 have been investigated by the combined use of X-ray powder diffraction, electron paramagnetic resonance (EPR), 7Li MAS NMR, and impedance spectroscopy techniques. The spinel structure of the lithium titanate is preserved and the lattice parameter decreases with increasing the Mn content. Mn2+ ions progressively occupy the tetrahedral site up to an approximately constant value reached for 10% Mn-substituted samples. Mn3+ ions occupy both octahedral and tetrahedral sites, with a constant value on the tetrahedral one, independent of the total Mn amount; Mn4+ ions are not detected. The Mn2+ paramagnetic ions give rise to a through-space interaction with Li+ ions of both cationic sites, as evaluated by the area, proportional to the Mn2+ ions content, of a peak at ∼8 ppm observed in the 7Li NMR spectra for the substituted samples. The obtained cation distribution and the Mn valence states satisfactorily explain the decrease of conductivity observed in the Mn-doped samples with respect to the pure Li4Ti5O12

Published

2008