Your search keyword '"Smogunov, Alexander"' showing total 3 results

1. Kondo conductance in an atomic nanocontact from first principles.

Author

Lucignano, Procolo, Mazzarello, Riccardo, Smogunov, Alexander, Fabrizio, Michele, and Tosatti, Erio

Subjects

DENSITY functionals, RENORMALIZATION group, ANTIFERROMAGNETISM, FERROMAGNETISM, METAMATERIALS

Abstract

The electrical conductance of atomic metal contacts represents a powerful tool for detecting nanomagnetism. Conductance reflects magnetism through anomalies at zero bias—generally with Fano line shapes—owing to the Kondo screening of the magnetic impurity bridging the contact. A full atomic-level understanding of this nutshell many-body system is of the greatest importance, especially in view of our increasing need to control nanocurrents by means of magnetism. Disappointingly, at present, zero-bias conductance anomalies are not calculable from atomistic scratch. Here, we demonstrate a working route connecting approximately but quantitatively density functional theory (DFT) and numerical renormalization group (NRG) approaches and leading to a first-principles conductance calculation for a nanocontact, exemplified by a Ni impurity in a Au nanowire. A Fano-like conductance line shape is obtained microscopically, and shown to be controlled by the impurity s-level position. We also find a relationship between conductance anomaly and geometry, and uncover the possibility of opposite antiferromagnetic and ferromagnetic Kondo screening—the latter exhibiting a totally different and unexplored zero-bias anomaly. The present matching method between DFT and NRG should permit the quantitative understanding and exploration of this larger variety of Kondo phenomena at more general magnetic nanocontacts. [ABSTRACT FROM AUTHOR]

Published

2009

2. Complex band structure with ultrasoft pseudopotentials: fcc Ni and Ni nanowire

Author

Smogunov, Alexander, Dal Corso, Andrea, and Tosatti, Erio

Subjects

*NICKEL, *DENSITY functionals

Abstract

We generalize to magnetic transition metals the approach proposed by Choi and Ihm for calculating the complex band structure of periodic systems, a key ingredient for future calculations of conductivity of an open quantum system within the Landauer–Buttiker theory. The method is implemented with ultrasoft pseudopotentials and plane wave basis set in a DFT-LSDA ab initio scheme. As a first example, we present the complex band structure of bulk fcc Ni (which constitutes the tips of a Ni nanocontact) and monatomic Ni wire (the junction between two tips). Based on our results, we anticipate some features of the spin-dependent conductance in a Ni nanocontact. [Copyright &y& Elsevier]

Published

2003

3. Effect of stretching on the ballistic conductance of Au nanocontacts in presence of CO: A density functional study.

Author

Sclauzero, Gabriele, Corso, Andrea Dal, and Smogunov, Alexander

Subjects

*ELECTRIC conductivity, *GOLD nanoparticles, *ELECTRIC contacts, *CARBON monoxide, *DENSITY functionals, *ADSORPTION (Chemistry), *NUMERICAL analysis

Abstract

CO adsorption on an Au monatomic chain is studied within density functional theory in nanocontact geometries as a function of the contact stretching. We compare the bridge and atop adsorption sites of CO, finding that the bridge site is energetically favored at all strains studied here. Atop adsorption gives rise to an almost complete suppression of the ballistic conductance of the nanocontact, while adsorption at the bridge site results in a conductance value close to 0.6 Go, in agreement with previous experimental data. We show that only the bridge site can qualitatively account for the evolution of the conductance as a function of the contact stretching observed in the experimental conductance traces. The numerical discrepancy between the theoretical and experimental conductance slopes is rationalized through a simple model for the elastic response of the metallic leads. We also verify that our conductance values are not affected by the specific choice of the nanocontact geometry by comparing two different atomistic models for the tips. [ABSTRACT FROM AUTHOR]

Published

2012