70,197 research outputs found
Propagation Phenomena for A Reaction-Advection-Diffusion Competition Model in A Periodic Habitat
This paper is devoted to the study of propagation phenomena for a
Lotka-Volterra reaction-advection-diffusion competition model in a periodic
habitat. We first investigate the global attractivity of a semi-trival steady
state for the periodic initial value problem. Then we establish the existence
of the rightward spreading speed and its coincidence with the minimal wave
speed for spatially periodic rightward traveling waves. We also obtain a set of
sufficient conditions for the rightward spreading speed to be linearly
determinate. Finally, we apply the obtained results to a prototypical
reaction-diffusion model
Partially Block Markov Superposition Transmission of Gaussian Source with Nested Lattice Codes
This paper studies the transmission of Gaussian sources through additive
white Gaussian noise (AWGN) channels in bandwidth expansion regime, i.e., the
channel bandwidth is greater than the source bandwidth. To mitigate the error
propagation phenomenon of conventional digital transmission schemes, we propose
in this paper a new capacity-approaching joint source channel coding (JSCC)
scheme based on partially block Markov superposition transmission (BMST) of
nested lattice codes. In the proposed scheme, first, the Gaussian source
sequence is discretized by a lattice-based quantizer, resulting in a sequence
of lattice points. Second, these lattice points are encoded by a short
systematic group code. Third, the coded sequence is partitioned into blocks of
equal length and then transmitted in the BMST manner. Main characteristics of
the proposed JSCC scheme include: 1) Entropy coding is not used explicitly. 2)
Only parity-check sequence is superimposed, hence, termed partially BMST
(PBMST). This is different from the original BMST. To show the superior
performance of the proposed scheme, we present extensive simulation results
which show that the proposed scheme performs within 1.0 dB of the Shannon
limits. Hence, the proposed scheme provides an attractive candidate for
transmission of Gaussian sources.Comment: 22 pages, 9 figures, Submitted to IEEE Transaction on Communication
Traveling waves and spreading speeds for time-space periodic monotone systems
The theory of traveling waves and spreading speeds is developed for
time-space periodic monotone semiflows with monostable structure. By using
traveling waves of the associated Poincar\'e maps in a strong sense, we
establish the existence of time-space periodic traveling waves and spreading
speeds. We then apply these abstract results to a two species competition
reaction-advection-diffusion model. It turns out that the minimal wave speed
exists and coincides with the single spreading speed for such a system no
matter whether the spreading speed is linearly determinate. We also obtain a
set of sufficient conditions for the spreading speed to be linearly
determinate.Comment: arXiv admin note: text overlap with arXiv:1410.459
Josephson Effects in Three-Band Superconductors with Broken Time-Reversal Symmetry
In superconductors with three or more bands, time-reversal symmetry (TRS) may
be broken in the presence of repulsive interband couplings, resulting in a pair
of degenerate states characterized by opposite chiralities. We consider a
Josephson junction between a three-band superconductor with broken TRS and a
single-band superconductor. Phenomena such as asymmetric critical currents,
subharmonic Shapiro steps and symmetric Fraunhhofer patterns are revealed
theoretically. Existing experimental results are discussed in terms of the
present work.Comment: 7 pages, 4 figures, Appl. Phys. Lett., in pres
Fractional Flux Plateau in Magnetization Curve of Multicomponent Superconductor Loop
Time-reversal symmetry (TRS) may be broken in superconductors with three or
more condensates interacting repulsively, yielding two degenerate states
specified by chirality of gap functions. We consider a loop of such
superconductor with two halves occupied by the two states with opposite
chiralities. Fractional flux plateaus are found in magnetization curve
associated with free-energy minima, where the two domain walls between the two
halves accommodate different inter-component phase kinks leading to finite
winding numbers in a part of the whole condensates around the loop. Fractional
flux plateaus form pairs with their heights related to the flux quantum {\Phi}0
= hc/2e. This phenomenon is a clear evidence of time-reversal symmetry broken
(TRSB) superconductivity, which in a general point of view provides a novel
chance to explore relative phase difference, phase kink and soliton in
ubiquitous multi-component superconductivity such as that in iron pnicitides.Comment: 8 pages, 7 figure
A parameterization of the canonical bases of affine modified quantized enveloping algebras
For symmetrizable Kac-Moody Lie algebra , Lusztig introduced the
modified quantized enveloping algebra and its
canonical basis in [12]. In this paper, for finite and affine type symmetric
Lie algebra we define a set which depend only on the root category
and prove that there is a bijection between the set and the canonical basis of
, where the root category is the -orbit
category of the derived category of Dynkin or tame quiver. Our method bases on
one theorem of Lin, Xiao and Zhang in [9], which gave the PBW-basis of
.Comment: 23 page
Geometric realizations of Lusztig's symmetries
In this paper, we give geometric realizations of Lusztig's symmetries. We
also give projective resolutions of a kind of standard modules. By using the
geometric realizations and the projective resolutions, we obtain the
categorification of the formulas of Lusztig's symmetries
Vortices with Fractional Flux Quanta in Multi-Band Superconductors
In superconductors with three or more components, time-reversal symmetry may
be broken when the inter-component couplings are repulsive, leading to a
superconducting state with two-fold degeneracy. When prepared carefully there
is a stable domain wall on a constriction which connects two bulks in states
with opposite chiralities. Applying on external magnetic field, vortices in
different components dissociate with each other, resulting in a ribbon shape
distribution of magnetic field at the position of domain wall.Comment: 4 pages, 4 figures, to appear on Journal of Superconductivity and
Novel Magnetis
Proposal for Observing Dynamic Jahn-Teller Effect of Single Solid-State Defects
Jahn-Teller effect (JTE) widely exists in polyatomic systems including
organic molecules, nano-magnets, and solid-state defects. Detecting the JTE at
single-molecule level can provide unique properties about the detected
individual object. However, such measurements are challenging because of the
weak signals associated with a single quantum object. Here, we propose that the
dynamic JTE of single defects in solids can be observed with nearby quantum
sensors. With numerical simulations, we demonstrate the real-time monitoring of
quantum jumps between different stable configurations of single substitutional
nitrogen defect centers (P1 centers) in diamond. This is achieved by measuring
the spin coherence of a single nitrogen-vacancy (NV) center near the P1 center
with the double electron-electron resonance (DEER) technique. Our work extends
the ability of NV center as a quantum probe to sense the rich physics in
various electron-vibrational coupled systems
BGP-Reflection Functors and Lusztig's Symmetries of Modified Quantized Enveloping Algebras
Let be the quantized enveloping algebra and
its modified form. Lusztig gives some symmetries on and
. Since the realization of by the reduced
Drinfeld double of the Ringel-Hall algebra, one can apply the BGP-reflection
functors to the double Ringel-Hall algebra to obtain Lusztig's symmetries on
and their important properties, for instance, the braid relations.
In this paper, we define a modified form of the Ringel-Hall
algebra and realize the Lusztig's symmetries on by applying
the BGP-reflection functors to .Comment: 23 page
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