2,129 research outputs found
Proposal for Plasmon Spectroscopy of Fluctuations in Low-Dimensional Superconductors
We propose to employ an optical spectroscopy technique to monitor the
superconductivity and properties of superconductors in the fluctuating regime.
This technique is operational close to the plasmon resonance frequency of the
material, and it intimately connects with the superconducting fluctuations
slightly above the critical temperature . We find the Aslamazov-Larkin
corrections to AC linear and DC nonlinear electric currents in a generic
two-dimensional system exposed to an external longitudinal electromagnetic
field. First, we study the plasmon resonance of normal electrons near ,
taking into account their interaction with superconducting fluctuations, and
show that fluctuating Cooper pairs reveal a redshift of the plasmon dispersion
and an additional mechanism of plasmon scattering, which surpasses both the
electron-impurity and the Landau dampings. Second, we demonstrate the emergence
of a drag effect of superconducting fluctuations by the external field
resulting in considerable, experimentally measurable corrections to the
electric current in the vicinity of the plasmon resonance.Comment: Manuscript: 6 pages (main text), 2 figures, and Supplemental
Material. Published in Phys. Rev. Letter
Photoinduced electric currents in Bose-Einstein condensates
We calculate a light-induced electric current which can occur from a
Bose-Einstein condensate under the action of an external electromagnetic field
with the frequency exceeding the ionization potential of the bosons, taking a
system of indirect excitons as a testbed. We show that the ionization can be
accompanied by the excitation of collective Bogoliubov modes. As a result, the
current consists of two principal components: one regular, which has a
counterpart in bosonic systems in the normal phase, and the other one specific
for condensates since the photoabsorption is mediated by the emission of
Bogoliubov quasiparticles. Surprisingly, the latter component soon becomes
predominant with the increase of light frequency above the ionization
potential.Comment: Manuscript: 5 pages, 2 figure
Paramagnetic resonance in spin-polarized disordered Bose-Einstein condensates
We study the pseudo-spin density response of a disordered two-dimensional
spin-polarized Bose gas of exciton polaritons to weak alternating magnetic
field, assuming that one of the spin states of the doublet is macroscopically
occupied and Bose-condensed while the occupation of the other state remains
much smaller. We calculate spatial and temporal dispersions of spin
susceptibility of the gas taking into account spin-flip processes due to the
transverse-longitudinal splitting. Further, we use the Bogoliubov theory of
weakly-interacting gases and show that the time-dependent magnetic field power
absorption exhibits double resonance structure corresponding to two particle
spin states (contrast to paramagnetic resonance in regular spin-polarized
electron gas). We analyze the widths of these resonances caused by scattering
on the disorder and show that, in contrast with the ballistic regime, in the
presence of impurities, the polariton scattering on them is twofold: scattering
on the impurity potential directly and scattering on the spatially fluctuating
condensate density caused by the disorder. As a result, the width of the
resonance associated with the Bose-condensed spin state can be surprizingly
narrow in comparison with the width of the resonance associated with the
non-condensed state.Comment: Manuscript: 6 pages, 2x2 figures, published in Scientific Reports 7,
2076 (2017
Bogolon-mediated electron capture by impurities in hybrid Bose-Fermi systems
We investigate the processes of electron capture by a Coulomb impurity center
residing in a hybrid system consisting of spatially separated two-dimensional
layers of electron and Bose-condensed dipolar exciton gases coupled via the
Coulomb forces. We calculate the probability of the electron capture
accompanied by the emission of a single Bogoliubov excitation (bogolon),
similar to regular phonon-mediated scattering in solids. Further, we study the
electron capture mediated by the emission of a pair of bogolons in a single
capture event and show that these processes not only should be treated in the
same order of the perturbation theory, but also they give more important
contribution than single bogolon-mediated capture, in contrast with regular
phonon scattering.Comment: Paper: 5 pages, 4 figure
Fuzzy simulation of forest road surface parameters
The problem of construction of forest roads with the use of local low-strength substandard materials and industrial waste is considered. To solve the problem, the primary task is to develop a method for estimating the parameters of road surfaces taking into account the conditions of uncertainties in the data. This technique allows us to reasonably clarify some of the regulatory parameters and improve the technology of construction of forest roads, which was the goal of the work. To formalize the task, experimental studies were performed and on the basis of these results, the statement of the task of fuzzy derivation of the function for estimating the bearing capacity of the coating was performed. The synthesis of the output function is performed by means of Matlab. © 2019 IOP Publishing Ltd. All rights reserved
Rashba plasmon polaritons in semiconductor heterostructures
We propose a concept of surface plasmon-polariton amplification in the
structure comprising interface between dielectric, metal and asymmetric quantum
well. Due to the Rashba spin-orbit interaction, mimina of dispersion relation
for electrons in conduction band are shifted with respect to the maximum of
dispersion dependence for holes in -point. When energy and momentum
intervals between extrema in dispersion relations of electrons and holes match
dispersion relation of plasmons, indirect radiative transition can amplify the
plasmons; excitation of leaky modes is forbidden due to the selection rules.
Efficiency of the indirect radiative transition is calculated and design of the
structure is analysed.Comment: Published (4 pages + 3 figures), 2nd proof versio
Radiation Pressure Quantization
Kepler's observation of comets tails initiated the research on the radiation
pressure of celestial objects and 250 years later they found new incarnation
after the Maxwell's equations were formulated to describe a plethora of
light-matter coupling phenomena. Further, quantum mechanics gave birth to the
photon drag effect. Here, we predict a novel universal phenomenon which can be
referred to as quantization of the radiation pressure. We develop a microscopic
theory of this effect which can be applied to a general system containing
Bose-Einstein-condensed particles, which possess an internal structure of
quantum states. By analyzing the response of the system to an external
electromagnetic field we find that such drag results in a flux of particles
constituting both the condensate and the excited states. We show that in the
presence of the condensed phase, the response of the system becomes quantized
which manifests itself in a step-like behavior of the particle flux as a
function of electromagnetic field frequency with the elementary quantum
determined by the internal energy structure of the particles.Comment: Manuscript: 4 pages, 3 figure
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