Your search keyword '"Di Valentin C"' showing total 6 results

1. Electronic structure of defect states in hydroxylated and reduced rutile TiO2(110) surfaces

Author

DI VALENTIN, CRISTIANA, PACCHIONI, GIANFRANCO, Selloni, A., DI VALENTIN, C, Pacchioni, G, and Selloni, A

Subjects

CHIM/03 - CHIMICA GENERALE E INORGANICA, ossidi, difetti, calcoli quantistici

Abstract

It has been experimentally observed that a bridging oxygen vacancy on the rutile TiO2(110) surface introduces localized Ti(3)3d(1) states about 1 eV below the conduction band which are not removed upon dissociation of a water molecule and formation of a pair of hydroxyl groups. Density functional calculations based on pure exchange-correlation functionals have not been able to satisfactorily reproduce and analyze these findings. Here we show that a correct description of the localized defect states on reduced and hydroxylated TiO2(110) is achieved only if proper geometry relaxation is accounted for using hybrid exchange functionals. We confirm the electron trapping nature of Ti(OH) groups but find no evidence that these defects should also act as hole traps by formation of Ti4(OH)(.) radicals.

Published

2006

2. Shaping Magnetite Nanoparticles from First Principles

Author

Cristiana Di Valentin, Hongsheng Liu, Liu, H, and Di Valentin, C

Subjects

Condensed Matter - Materials Science, Materials science, Magnetic moment, Basis (linear algebra), Condensed matter physics, Iron oxide, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, General Physics and Astronomy, ING-IND/22 - SCIENZA E TECNOLOGIA DEI MATERIALI, 01 natural sciences, Charge ordering, chemistry.chemical_compound, Tight binding, chemistry, 0103 physical sciences, Empirical formula, Magnetic nanoparticles, Density functional theory, 010306 general physics, Magnetic nanoparticles, Nanoparticles, Smart materials, Density Functional Tight Binding, Density functional theory

Abstract

Iron oxide magnetic nanoparticles (NPs) are stimuli-responsive materials at the forefront of nanomedicine. Their realistic finite temperature simulations are a formidable challenge for first-principles methods. Here, we use density functional tight binding to open up the required time and length scales and obtain global minimum structures of ${\mathrm{Fe}}_{3}{\mathrm{O}}_{4}$ NPs of realistic size (1400 atoms, 2.5 nm) and of different shapes, which we then refine with hybrid density functional theory methods to accomplish proper electronic and magnetic properties, which have never been accurately described in simulations. On this basis, we develop a general empirical formula and prove its predictive power for the evaluation of the total magnetic moment of ${\mathrm{Fe}}_{3}{\mathrm{O}}_{4}$ NPs. By converting the total magnetic moment into the macroscopic saturation magnetization, we rationalize the experimentally observed dependence with shape. We also reveal interesting reconstruction mechanisms and unexpected patterns of charge ordering.

3. Shaping Magnetite Nanoparticles from First Principles.

Author

Liu H and Di Valentin C

Abstract

Iron oxide magnetic nanoparticles (NPs) are stimuli-responsive materials at the forefront of nanomedicine. Their realistic finite temperature simulations are a formidable challenge for first-principles methods. Here, we use density functional tight binding to open up the required time and length scales and obtain global minimum structures of Fe_{3}O_{4} NPs of realistic size (1400 atoms, 2.5 nm) and of different shapes, which we then refine with hybrid density functional theory methods to accomplish proper electronic and magnetic properties, which have never been accurately described in simulations. On this basis, we develop a general empirical formula and prove its predictive power for the evaluation of the total magnetic moment of Fe_{3}O_{4} NPs. By converting the total magnetic moment into the macroscopic saturation magnetization, we rationalize the experimentally observed dependence with shape. We also reveal interesting reconstruction mechanisms and unexpected patterns of charge ordering.

Published

2019

4. Shallow donor states induced by in-diffused Cu in ZnO: a combined HREELS and hybrid DFT study.

Author

Qiu H, Gallino F, Di Valentin C, and Wang Y

Abstract

A combined experimental and first principles study of Cu defects in bulk ZnO is presented. Cu particles are epitaxially deposited on the polar O-ZnO(0001) surface at room temperature. Upon heating, a broadening of the quasielastic peak in high resolution electron energy loss spectra is observed, corresponding to an electronic doping effect of Cu atoms in bulk ZnO with an ionization energy of 88 meV. Cu impurities in ZnO, although commonly acting as acceptors, are presently observed to induce shallow donor states. We assign these to interstitial Cu species on the basis of a hybrid density functional study.

Published

2011

5. Surface structure of TiO2(011)-(2x1).

Author

Beck TJ, Klust A, Batzill M, Diebold U, Di Valentin C, and Selloni A

Abstract

A combined experimental and first principles study of the (2x1)-reconstructed rutile TiO2(011) surface is presented. Our results provide evidence that the surface structure is described by a model that includes onefold coordinated (titanyl) oxygen atoms giving rise to double bonded Ti=O species. These species should play a special role in the enhanced photocatalytic activity of the TiO2(011) surface.

Published

2004

6. Nucleation of Pd dimers at defect sites of the MgO(100) surface.

Author

Giordano L, Di Valentin C, Goniakowski J, and Pacchioni G

Abstract

Point defects on oxide surfaces are presumed to be preferential nucleation sites for supported metal clusters. Under typical growth conditions, dimers constitute the first step in island nucleation. First-principles calculations on the formation of Pd dimers on regular and defect sites of the MgO(100) surface show that nucleation occurs with large dimer binding energies at divacancies and charged oxygen vacancies (F+ centers), while it is less favorable on steps and neutral F centers. The extensive database of defect trapping/attachment properties gives a firm basis to rationalize recent atomic-force microscopy findings and provides guidelines valid, in general, for ionic substrates.

Published

2004