3,406 research outputs found
Competition of Color Ferromagnetic and Superconductive States in a Quark-Gluon System
The possibility of color ferromagnetism in an SU(2) gauge field model is
investigated. The conditions allowing a stable color ferromagnetic state of the
quark system in the chromomagnetic field occupying small domains are
considered. A phase transition between this state and the color superconducting
state is considered. The effect of finite temperature is analyzed.Comment: 21 pages, 4 Postscript figure
Surface Electronic Structures and Field Emission Currents at Sodium Overlayers on Low-Index Tungsten Surfaces
The total energy distributions (TEDs) of the emission currents in field
emission and surface photofield emission and the overlayer-induced
modifications in the surface electronic structures from the technologically
important W surfaces with the commensurate W(100)/Na c(2x2), W(110)/Na (2x2)
and W(111)/Na (1x1) overlayers are calculated. The TEDs obtained by our recent
numerical method that extends the full-potential linear augmented plane wave
method for the electronic structures to the study of field and photofield
emission are used to interpret the shifts of the peaks in the experimental TEDs
in field emission and photofield emission from the W(100) and W(110) surfaces
at sub-monolayer and monolayer Na coverage. Hybridization of the 3s Na states
with the pairs of dz2-like surface states of the strong Swanson hump in clean
W(100) and surface resonances in clean W(111) below the Fermi energy shifts
these W states by about -1.2 eV and -1.0 eV, thus stabilizing these states, to
yield new strong peaks in the TEDs in field emission and photofield emission
from W(100)/Na c(2x2) and W(111)/Na (1x1) respectively. The effect of Na
intralayer interactions are discussed and are shown to shift the strong s- and
p-like peaks in the surface density of states of W(110) below and above the
Fermi energy respectively to lower energy with increased Na coverage, in
agreement with experiments.Comment: 12 page
Size effects in radiospectroscopy spectra of ferroelectric nanopowders
The theoretical and experimental investigation of ferroelectric nanopowders
is performed. The manifestation in radiospectroscopy spectra of size driven
ferroelectric-paraelectric phase transition at some critical particle average
size was the main goal of the consideration. In theoretical part the size
effect for the materials with ferroelectric tetragonal phase and cubic
paraelectric phase was considered allowing for the spontaneous polarization
inhomogeneity inside a particle and distribution of particle sizes. In ESR the
transformation of the spectra from tetragonal symmetry to cubic symmetry with
decreasing of nanoparticle sizes was calculated. Measurements of Fe3+ ESR
spectra in nanopowder of BaTiO3 were carried out at room temperature. The
decrease of intensity of tetragonal symmetry ESR lines of Fe3+ and appearance
of cubic symmetry line with asymmetry of the shoulders was observed with the
average sizes decrease with complete disappearance of tetragonal spectrum at
average size less or equal 40 nm. The comparison of the theory with experiment
was carried out. The value of critical size Rc = 40 nm was extracted from ESR
data. The asymmetry and broadening of right hand side shoulder of ESR cubic
symmetry line was shown to be related to contribution of paramagnetic centers
in the vicinity of the particles surface. The deconvolution of the cubic line
allowed to show, that this region size is about 3 nm.Comment: 10 pages, 8 figure
Counting Berg partitions
We call a Markov partition of a two dimensional hyperbolic toral automorphism
a Berg partition if it contains just two rectangles. We describe all Berg
partitions for a given hyperbolic toral automorphism. In particular there are
exactly (k + n + l + m)/2 nonequivalent Berg partitions with the same
connectivity matrix (k, l, m, n)
Magnetic Susceptibility of the Quark Condensate and Polarization from Chiral Models
We compute the magnetic susceptibility of the quark condensate and the
polarization of quarks at zero temperature and in a uniform magnetic
background. Our theoretical framework consists of two chiral models that allow
to treat self-consistently the spontaneous breaking of chiral symmetry: the
linear model coupled to quarks, dubbed quark-meson model, and the
Nambu-Jona-Lasinio model. We also perform analytic estimates of the same
quantities within the renormalized quark-meson model, both in the regimes of
weak and strong fields. Our numerical results are in agreement with the recent
literature; moreover, we confirm previous Lattice findings, related to the
saturation of the polarization at large fields.Comment: 13 pages, 4 figure
Fermion Condensate and Vacuum Current Density Induced by Homogeneous and Inhomogeneous Magnetic Fields in (2+1)-Dimensions
We calculate the condensate and the vacuum current density induced by
external static magnetic fields in (2+1)-dimensions. At the perturbative level,
we consider an exponentially decaying magnetic field along one cartesian
coordinate. Non-perturbatively, we obtain the fermion propagator in the
presence of a uniform magnetic field by solving the Schwinger-Dyson equation in
the rainbow-ladder approximation. In the large flux limit, we observe that both
these quantities, either perturbative (inhomogeneous) and non-perturbative
(homogeneous), are proportional to the external field, in agreement with early
expectations.Comment: 8 pages, 2 figures. Accepted for publication in Phys. Rev.
The four-fermion interaction in D=2,3,4: a nonperturbative treatment
A new nonperturbative approach is used to investigate the Gross-Neveu model
of four fermion interaction in the space-time dimensions 2, 3 and 4, the number
of inner degrees of freedom being a fixed integer. The spontaneous symmetry
breaking is shown to exist in and the running coupling constant is
calculated. The four dimensional theory seems to be trivial.Comment: a minor correction: one more acknowledgement is added. Latex 2.09
file, 15 pages, no figures, accepted for publication to Int.J.Mod.Phys.
Enhancing the significance of gravitational wave bursts through signal classification
The quest to observe gravitational waves challenges our ability to
discriminate signals from detector noise. This issue is especially relevant for
transient gravitational waves searches with a robust eyes wide open approach,
the so called all- sky burst searches. Here we show how signal classification
methods inspired by broad astrophysical characteristics can be implemented in
all-sky burst searches preserving their generality. In our case study, we apply
a multivariate analyses based on artificial neural networks to classify waves
emitted in compact binary coalescences. We enhance by orders of magnitude the
significance of signals belonging to this broad astrophysical class against the
noise background. Alternatively, at a given level of mis-classification of
noise events, we can detect about 1/4 more of the total signal population. We
also show that a more general strategy of signal classification can actually be
performed, by testing the ability of artificial neural networks in
discriminating different signal classes. The possible impact on future
observations by the LIGO-Virgo network of detectors is discussed by analysing
recoloured noise from previous LIGO-Virgo data with coherent WaveBurst, one of
the flagship pipelines dedicated to all-sky searches for transient
gravitational waves
Prospects for intermediate mass black hole binary searches with advanced gravitational-wave detectors
We estimated the sensitivity of the upcoming advanced, ground-based
gravitational-wave observatories (the upgraded LIGO and Virgo and the KAGRA
interferometers) to coalescing intermediate mass black hole binaries (IMBHB).
We added waveforms modeling the gravitational radiation emitted by IMBHBs to
detectors' simulated data and searched for the injected signals with the
coherent WaveBurst algorithm. The tested binary's parameter space covers
non-spinning IMBHBs with source-frame total masses between 50 and 1050
and mass ratios between and 1. We found that
advanced detectors could be sensitive to these systems up to a range of a few
Gpc. A theoretical model was adopted to estimate the expected observation
rates, yielding up to a few tens of events per year. Thus, our results indicate
that advanced detectors will have a reasonable chance to collect the first
direct evidence for intermediate mass black holes and open a new, intriguing
channel for probing the Universe over cosmological scales.Comment: 9 pages, 4 figures, corrected the name of one author (previously
misspelled
Age features of O2 mass transfer regimes in adolescents’ body at rest
The results of complex studies of the quantitative relationship between the stage-by-stage mass transfer of O2 and the efficiency of cardiorespiratory system functioning in relation to its consumption in adolescents’ body under conditions of relative rest are presented.
The results obtained show that in adolescents, the modes of mass transfer of O2 in the body and the nature of the respiratory and circulatory systems functioning in relation to its consumption have a number of age-related differences compared with adult men. So, in adolescents, the external respiration system at rest functions less economically than in adults. Each liter of O2 consumed by adolescents is extracted from almost 3 liters more than in adults the amount of air ventilated per minute through the lungs. The volumetric indicators of blood circulation are also higher in adolescents, which may indicate the influence of neuro-humoral rearrangements in the body during the pubertal period. The coefficient of oxygen utilization by tissues from arterial blood in adolescents turned out to be significantly higher, which may characterize a higher tension of tissue metabolic processes
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