268 research outputs found
Influence of Dynamics on Magic Numbers for Silicon Clusters
We present the results of over 90 tight-binding molecular-dynamics
simulations of collisions between three- and five-atom silicon clusters, at a
system temperature of 2000K. Much the most likely products are found to be two
'magic' four-atom clusters. We show that previous studies, which focused on the
equilibrium binding energies of clusters of different sizes, are of limited
relevance, and introduce a new effective binding energy which incorporates the
highly anharmonic dynamics of the clusters. The inclusion of dynamics enhances
the magic nature of both Si4 and Si6 and destroys that of Si7.Comment: 12 pages, 3 Figures, 500 KB gzipped PostScript fil
Density-functional theory and the v-representability problem for model strongly correlated electron systems
Inspired by earlier work on the band-gap problem in insulators, we reexamine
the treatment of strongly correlated Hubbard-type models within
density-functional theory. In contrast to previous studies, the density is
fully parametrized by occupation numbers and overlap of orbitals centered at
neighboring atomic sites, as is the local potential by the hopping matrix. This
corresponds to a good formal agreement between density-functional theory in
real space and second quantization. It is shown that density-functional theory
is formally applicable to such systems and the theoretical framework is
provided. The question of noninteracting v representability is studied
numerically for finite one-dimensional clusters, for which exact results are
available, and qualitatively for infinite systems. This leads to the conclusion
that the electron density corresponding to interacting systems of the type
studied here is in fact not noninteracting v representable because the
Kohn-Sham electrons are unable to reproduce the correlation-induced
localization correctly.Comment: 9 pages including 1 figur
Exact density-functional potentials for time-dependent quasiparticles
We calculate the exact Kohn-Sham potential that describes, within
time-dependent density-functional theory, the propagation of an electron
quasiparticle wavepacket of non-zero crystal momentum added to a ground-state
model semiconductor. The potential is observed to have a highly nonlocal
functional dependence on the charge density, in both space and time, giving
rise to features entirely lacking in local or adiabatic approximations. The
dependence of the non-equilibrium part of the Kohn-Sham electric field on the
local current and charge density is identified as a key element of the correct
Kohn-Sham functional.Comment: 4 pages, 3 figure
Quantum conductance of homogeneous and inhomogeneous interacting electron systems
We obtain the conductance of a system of electrons connected to leads, within
time-dependent density-functional theory, using a direct relation between the
conductance and the density response function. Corrections to the
non-interacting conductance appear as a consequence of the functional form of
the exchange-correlation kernel at small frequencies and wavevectors. The
simple adiabatic local-density approximation and non-local density-terms in the
kernel both give rise to significant corrections in general. In the homogeneous
electron gas, the former correction remains significant, and leads to a failure
of linear-response theory for densities below a critical value.Comment: for resolution of the here published results see Phys. Rev. B 76,
125433 (2007
Current-constraining variational approaches to quantum transport
Presently, the main methods for describing a nonequilibrium charge-transporting steady state are based on time-evolving it from the initial zero-current situation. An alternative class of theories would give the statistical nonequilibrium density operator from principles of statistical mechanics, in a spirit close to Gibbs ensembles for equilibrium systems, leading to a variational principle for the nonequilibrium steady state. We discuss the existing attempts to achieve this using the maximum entropy principle based on constraining the average current. We show that the current-constrained theories result in a zero-induced drop in electrostatic potential, so that such ensembles cannot correspond to the time-evolved density matrix, unless left- and right-going scattering states are mutually incoherent
Comment on "Dynamical corrections to the DFT-LDA electron conductance in nanoscale systems"
In a recent paper Sai et al. [1] identified a correction R^{dyn}R=R_{s}+R^{dyn}R_{s}XCR^{dyn}$ in example systems of the type they considered should be considerably reduced, once a more appropriate form for the shear electron viscosity ¿ is used
Stroboscopic wave-packet description of nonequilibrium many-electron problems
We introduce the construction of an orthogonal wave-packet basis set, using the concept of stroboscopic time propagation, tailored to the efficient description of nonequilibrium extended electronic systems. Thanks to three desirable properties of this basis, significant insight is provided into nonequilibrium processes (both time-dependent and steady-state), and reliable physical estimates of various many-electron quantities such as density, current, and spin polarization can be obtained. Use of the wave-packet basis provides new results for time-dependent switching-on of the bias in quantum transport, and for current-induced spin accumulation at the edge of a 2D doped semiconductor caused by edge-induced spin-orbit interaction
Self-interaction in Green's-function theory of the hydrogen atom
Atomic hydrogen provides a unique test case for computational electronic structure methods, since its electronic excitation energies are known analytically. With only one electron, hydrogen contains no electronic correlation and is therefore particularly susceptible to spurious self-interaction errors introduced by certain computational methods. In this paper we focus on many-body perturbation-theory (MBPT) in Hedin's GW approximation. While the Hartree-Fock and the exact MBPT self-energy are free of self-interaction, the correlation part of the GW self-energy does not have this property. Here we use atomic hydrogen as a benchmark system for GW and show that the self-interaction part of the GW self-energy, while non-zero, is small. The effect of calculating the GW self-energy from exact wavefunctions and eigenvalues, as distinct from those from the local-density approximation, is also illuminating
Assessment of density-functional approximations: Long-range correlations and self-interaction effects
The complex nature of electron-electron correlations is made manifest in the very simple but nontrivial problem of two electrons confined within a sphere. The description of highly nonlocal correlation and self-interaction effects by widely used local and semilocal exchange-correlation energy density functionals is shown to be unsatisfactory in most cases. Even the best such functionals exhibit significant errors in the Kohn-Sham potentials and density profiles
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