Assessment of Functionals for First-Principle Studies of the Structural and Electronic Properties of -Bi2O3

Fully relativistic full-potential density functional calculations with an all-electron linearized augmented plane waves plus local orbitals method were carried out to perform a comparative study on the structural and electronic properties of the cubic oxide -Bi2O3 phase, which is considered as one of the most promising materials in a variety of applications including fuel cells, sensors, and catalysts. Three different density functionals were used in our calculations, LDA, the GGA scheme in the parametrization of Perdew, Burke, and Ernzerhof (PBE96), and the hybrid scheme of Perdew-Wang B3PW91. The examined properties include lattice parameter, band structure and density of states, and charge density profiles. For this modification the three functionals reveal the characteristics of a metal and the existence of minigaps at high symmetry points of the band structure when spin-orbit coupling is taken into account. Density of states exhibits hybridization of Bi 6s and O 2p orbitals and the calculated charge density profiles exhibit the ionic character in the chemical bonding of this compound. The B3PW91 hybrid functional provided a better agreement with the experimental result for the lattice parameter, revealing the importance of Hartree-Fock exchange in this compound

Structure and Stability of an Amorphous Metal

Using molecular dynamics simulations, with a realistic many-body embedded-atom potential, and a novel method to characterize local order, we study the structure of pure nickel during the rapid quench of the liquid and in the resulting glass. In contrast with previous simulations with pair potentials, we find more crystalline order and fewer icosahedra for slower quenching rates, resulting in a glass less stable against crystallization. It is shown that there is not a specific amorphous structure, only the arrest of the transition from liquid to crystal, resulting in small crystalline clusters immersed in an amorphous matrix with the same structure of the liquid.Comment: 4 pages, 4 ps figs., to appear in Phys. Rev. Let

Experimental and theoretical study of the electronic properties Of COSi2 and NiSi2

Electronic structure of Co and Ni silicides were studied by means of the spectral properties of XPS high-resolution measurements together with theoretical calculations using crystal orbital overlap population (COOP) analysis. Calculations were carried out for CoSi2 and NiSi2 microstructures. Analysis from calculations shows that hybridization is stronger in Co disilicide than in Ni disilicide. Close to the Fermi level, we noticed that for the Co disilicide there is a small distribution (bonding and antibonding) to the total COOP, while the contribution from the Ni disilicide is null. XPS analysis of sample under study gives evidence about the covalent bonding when the chemical shifts for the Co 2p(3/2), Ni 2p(3/2) and Si 2p transitions are analyzed in the depth-profile mode. (C) 2004 Published by Elsevier B.V

Molecular dynamics and DFT study of 38-atom coinage metal clusters

The thermal behavior of 38-atom mono-, bi-, and trimetallic clusters consisting of Cu, Ag, and Au atoms, is analyzed employing molecular dynamics simulations and DFT calculations for selected cluster compositions. Low-energy structures were singled out to perform NVT molecular dynamics simulations at several temperatures, using the Andersen thermostat for temperature control. The caloric curve is used to estimate the melting temperature and the specific heat. The pair distribution function g(r) of the solid and liquid-phase clusters is examined at different temperatures. When comparing the estimated melting points (Tm) among the monatomic clusters, the order becomes TmCu38>TmAg38>TmAu38. For bimetallic clusters, an increase of Tm is observed for Cu-Au compared to their monatomic counterparts, while the opposite occurs for Cu-Ag clusters. For trimetallic clusters, two low-energy isomers of the Cu36Ag1Au1 cluster are investigated. In this case, Tm is estimated to be 475 K, for the two isomers with the lowest-energy and second-to-lowest energy, respectively. For all the clusters studied, the pair distribution function g(r) shows that the first peak position is not shifted as an effect of temperature and its maximum value varies with composition, while the second peak essentially vanishes upon melting. The common-neighbor analysis (CNA) technique is used to analyze the local structural changes for the trimetallic clusters, again demonstrating a clear structural change upon melting. The HOMO-LUMO energy gap indicates that the trimetallic isomers\u27 behavior is metallic, while the average binding energy show these clusters\u27 energetic stability to be similar

Theoretical Investigation of Photoinduced Processes in Subnanometer Oxide-Supported Metal Catalysts

We report a computational study and analysis of the optical absorption and photodecay processes in two subnanometer metal complexes deposited on an oxide support, the regular MgO(100) surface: (i) Ag3(HCO3)(C2H4)2(O) and (ii) Ag3(CO2F)(C2H4)2(O). These aggregates are chosen as derivatives of a Ag3(CO3)(C2H4)2(O) ligand/metal-cluster/support complex, previously singled out as a key intermediate in the path of ethylene partial oxidation to ethylene epoxide catalyzed by Ag3/MgO(100), and serve as model systems to investigate photochemical phenomena in ligand/metal-cluster/support complexes by subnanometer metal catalysts, an appealing field for future research. After generating optimized initial configurations and building cluster models that take properly into account the effect of the charge-separated oxide support, we use time-dependent density-functional theory (TDDFT) to determine first the photoabsorption spectra of the two aggregates and then to follow the evolution of their excited states in the optical region. We show that complexes containing such bicarbonate and fluorocarbonate groups are sensitive to optical adsorption, often leading to ligand detachment and/or cluster disaggregation, thus pointing to an "optical frailty"of these subnanometer cluster species, possibly rationalizing previous experimental observations. Additionally, we correlate the nature of the given excitations and of the corresponding photoinduced reaction products via an analysis of overlap population-density of states (OP-DOS), geometric parameters, and spatial distribution of the molecular orbitals involved in the excitation, thus providing the set of methodological tools needed to explore this novel field

Experimental and theoretical DOS of Co and Ni silicides

A set of samples of Co-Ni silicide thin-films were deposited on Si wafers by PLD and were submitted to thermal-annealing to promote silicidation. Samples were characterized by XPS, including in-depth profiles. Experimental results are complemented with theoretical density of states (DOS). Calculations were performed by means of extended HUM theory approximation. Tendency of DOS behavior of Co and Ni silicides at valence level about similarities/differences between theoretical calculations and experimental results is discussed alongside this work. (C) 2003 Elsevier Science B.V. All rights reserved