7,720 research outputs found
Re-entrant localization of single particle transport in disordered Andreev wires
We study effects of disorder on the low energy single particle transport in a
normal wire surrounded by a superconductor. We show that the heat conductance
includes the Andreev diffusion decreasing with increase in the mean free path
and the diffusive drift produced by a small particle-hole asymmetry,
which increases with increasing . The conductance thus has a minimum as a
function of which leads to a peculiar re-entrant localization as a
function of the mean free path.Comment: 4 pages, 2 figure
A quantum hydrodynamics approach to the formation of new types of waves in polarized two-dimension systems of charged and neutral particles
In this paper we explicate a method of quantum hydrodynamics (QHD) for the
study of the quantum evolution of a system of polarized particles. Though we
focused primarily on the two-dimension physical systems, the method is valid
for three-dimension and one-dimension systems too. The presented method is
based upon the Schr\"{o}dinger equation. Fundamental QHD equations for charged
and neutral particles were derived from the many-particle microscopic
Schr\"{o}dinger equation. The fact that particles possess the electric dipole
moment (EDM) was taken into account. The explicated QHD approach was used to
study dispersion characteristics of various physical systems. We analyzed
dispersion of waves in a two-dimension (2D) ion and hole gas placed into an
external electric field which is orthogonal to the gas plane. Elementary
excitations in a system of neutral polarized particles were studied for 1D, 2D
and 3D cases. The polarization dynamics in systems of both neutral and charged
particles is shown to cause formation of a new type of waves as well as changes
in the dispersion characteristics of already known waves. We also analyzed wave
dispersion in 2D exciton systems, in 2D electron-ion plasma and 2D
electron-hole plasma. Generation of waves in 3D system neutral particles with
EDM by means of the beam of electrons and neutral polarized particles is
investigated.Comment: 15 pages, 7 figure
Non-divergent pseudo-potential treatment of spin-polarized fermions under 1D and 3D harmonic confinement
Atom-atom scattering of bosonic one-dimensional (1D) atoms has been modeled
successfully using a zero-range delta-function potential, while that of bosonic
3D atoms has been modeled successfully using Fermi-Huang's regularized s-wave
pseudo-potential. Here, we derive the eigenenergies of two spin-polarized 1D
fermions under external harmonic confinement interacting through a zero-range
potential, which only acts on odd-parity wave functions, analytically. We also
present a divergent-free zero-range potential treatment of two spin-polarized
3D fermions under harmonic confinement. Our pseudo-potential treatments are
verified through numerical calculations for short-range model potentials.Comment: 9 pages, 4 figures (subm. to PRA on 03/15/2004
ДИНАМИКА ПРИРОДНОЙ СРЕДЫ МОНГОЛЬСКОГО АЛТАЯ В ГОЛОЦЕНЕ = [Environmental changes in the Mongolian Altai during the Holocene¡]
Diagrammatic method of integration over the unitary group, with applications to quantum transport in mesoscopic systems
A diagrammatic method is presented for averaging over the circular ensemble
of random-matrix theory. The method is applied to phase-coherent conduction
through a chaotic cavity (a ``quantum dot'') and through the interface between
a normal metal and a superconductor.Comment: 37 pages RevTeX, 21 postscript figures include
Two-photon correlations as a sign of sharp transition in quark-gluon plasma
The photon production arising due to time variation of the medium has been
considered. The Hamilton formalism for photons in time-variable medium (plasma)
has been developed with application to inclusive photon production. The results
have been used for calculation of the photon production in the course of
transition from quark-gluon phase to hadronic phase in relativistic heavy ion
collisions. The relative strength of the effect as well as specific two- photon
correlations have been evaluated. It has been demonstrated that the opposite
side two-photon correlations are indicative of the sharp transition from the
quark-gluon phase to hadrons.Comment: 23 pages, 2 figure
Optical properties of self-organized wurtzite InN/GaN quantum dots: A combined atomistic tight-binding and full configuration interaction calculation
In this work we investigate the electronic and optical properties of
self-assembled InN/GaN quantum dots. The one-particle states of the
low-dimensional heterostructures are provided by a tight-binding model that
fully includes the wurtzite crystal structure on an atomistic level. Optical
dipole and Coulomb matrix elements are calculated from these one-particle wave
functions and serve as an input for full configuration interaction
calculations. We present multi-exciton emission spectra and discuss in detail
how Coulomb correlations and oscillator strengths are changed by the
piezoelectric fields present in the structure. Vanishing exciton and biexciton
ground state emission for small lens-shaped dots is predicted.Comment: 3 pages, 2 figure
Relativistic Klein-Gordon-Maxwell multistream model for quantum plasmas
A multistream model for spinless electrons in a relativistic quantum plasma
is introduced by means of a suitable fluid-like version of the
Klein-Gordon-Maxwell system. The one and two-stream cases are treated in
detail. A new linear instability condition for two-stream quantum plasmas is
obtained, generalizing the previously known non-relativistic results. In both
the one and two-stream cases, steady-state solutions reduce the model to a set
of coupled nonlinear ordinary differential equations, which can be numerically
solved, yielding a manifold of nonlinear periodic and soliton structures. The
validity conditions for the applicability of the model are addressed
Coexisting ordinary elasticity and superfluidity in a model of defect-free supersolid
We present the mechanics of a model of supersolid in the frame of the
Gross-Pitaevskii equation at that do not require defects nor vacancies.
A set of coupled nonlinear partial differential equations plus boundary
conditions is derived. The mechanical equilibrium is studied under external
constrains as steady rotation or external stress. Our model displays a
paradoxical behavior: the existence of a non classical rotational inertia
fraction in the limit of small rotation speed and no superflow under small (but
finite) stress nor external force. The only matter flow for finite stress is
due to plasticity.Comment: 6 pages, 2 figure
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