528 research outputs found
Explicit Formulas for Relaxed Disarrangement Densities Arising from Structured Deformations
Structured deformations provide a multiscale geometry that captures the
contributions at the macrolevel of both smooth geometrical changes and
non-smooth geometrical changes (disarrangements) at submacroscopic levels. For
each (first-order) structured deformation of a continuous body, the
tensor field is known to be a measure of deformations without
disarrangements, and is known to be a measure of deformations
due to disarrangements. The tensor fields and together deliver not only
standard notions of plastic deformation, but and its curl deliver the
Burgers vector field associated with closed curves in the body and the
dislocation density field used in describing geometrical changes in bodies with
defects. Recently, Owen and Paroni [13] evaluated explicitly some relaxed
energy densities arising in Choksi and Fonseca's energetics of structured
deformations [4] and thereby showed: (1) , the positive part of
, is a volume density of disarrangements due to submacroscopic
separations, (2) , the negative part of , is a volume density
of disarrangements due to submacroscopic switches and interpenetrations, and
(3) , the absolute value of , is a volume density of all three of
these non-tangential disarrangements: separations, switches, and
interpenetrations. The main contribution of the present research is to show
that a different approach to the energetics of structured deformations, that
due to Ba\'ia, Matias, and Santos [1], confirms the roles of ,
, and established by Owen and Paroni. In doing so, we give
an alternative, shorter proof of Owen and Paroni's results, and we establish
additional explicit formulas for other measures of disarrangements.Comment: 17 pages; http://cvgmt.sns.it/paper/2776
Effect of Nonlinearity on Adiabatic Evolution of Light
We investigate the effect of nonlinearity in a system described by an adiabatically evolving Hamiltonian. Experiments are conducted in a three-core waveguide structure that is adiabatically varying with distance, in analogy to the stimulated Raman adiabatic passage process in atomic physics. In the linear regime, the system exhibits an adiabatic power transfer between two waveguides which are not directly coupled, with negligible power recorded in the intermediate coupling waveguide. In the presence of nonlinearity the adiabatic light passage is found to critically depend on the excitation power. We show how this effect is related to the destruction of the dark state formed in this configuration
High-Order-Mode Soliton Structures in Two-Dimensional Lattices with Defocusing Nonlinearity
While fundamental-mode discrete solitons have been demonstrated with both
self-focusing and defocusing nonlinearity, high-order-mode localized states in
waveguide lattices have been studied thus far only for the self-focusing case.
In this paper, the existence and stability regimes of dipole, quadrupole and
vortex soliton structures in two-dimensional lattices induced with a defocusing
nonlinearity are examined by the theoretical and numerical analysis of a
generic envelope nonlinear lattice model. In particular, we find that the
stability of such high-order-mode solitons is quite different from that with
self-focusing nonlinearity. As a simple example, a dipole (``twisted'') mode
soliton which may be stable in the focusing case becomes unstable in the
defocusing regime. Our results may be relevant to other two-dimensional
defocusing periodic nonlinear systems such as Bose-Einstein condensates with a
positive scattering length trapped in optical lattices.Comment: 14 pages, 10 figure
Realization of quantum walks with negligible decoherence in waveguide lattices
Quantum random walks are the quantum counterpart of classical random walks, and were recently studied in the context of quantum computation. Physical implementations of quantum walks have only been made in very small scale systems severely limited by decoherence. Here we show that the propagation of photons in waveguide lattices, which have been studied extensively in recent years, are essentially an implementation of quantum walks. Since waveguide lattices are easily constructed at large scales and display negligible decoherence, they can serve as an ideal and versatile experimental playground for the study of quantum walks and quantum algorithms. We experimentally observe quantum walks in large systems (similar to 100 sites) and confirm quantum walks effects which were studied theoretically, including ballistic propagation, disorder, and boundary related effects
New CMOS Compatible Platforms for Integrated Nonlinear Optical Signal Processing
Nonlinear photonic chips have succeeded in generating and processing signals
all-optically with performance far superior to that possible electronically -
particularly with respect to speed. Although silicon-on-insulator has been the
leading platform for nonlinear optics, its high two-photon absorption at
telecommunications wavelengths poses a fundamental limitation. This paper
reviews some of the recent achievements in CMOS-compatible platforms for
nonlinear optics, focusing on amorphous silicon and Hydex glass, highlighting
their potential future impact as well as the challenges to achieving practical
solutions for many key applications. These material systems have opened up many
new capabilities such as on-chip optical frequency comb generation and
ultrafast optical pulse generation and measurement.Comment: 8 pages, 10 figures 80 references. arXiv admin note: substantial text
overlap with arXiv:1404.561
Phase-Insensitive Scattering of Terahertz Radiation
The nonlinear interaction between Near-Infrared (NIR) and Terahertz pulses is
principally investigated as a means for the detection of radiation in the
hardly accessible THz spectral region. Most studies have targeted second-order
nonlinear processes, given their higher efficiencies, and only a limited number
have addressed third-order nonlinear interactions, mainly investigating
four-wave mixing in air for broadband THz detection. We have studied the
nonlinear interaction between THz and NIR pulses in solid-state media
(specifically diamond), and we show how the former can be frequency-shifted up
to UV frequencies by the scattering from the nonlinear polarisation induced by
the latter. Such UV emission differs from the well-known electric-field-induced
second harmonic (EFISH) one, as it is generated via a phase-insensitive
scattering, rather than a sum- or difference-frequency four-wave-mixing
process
Design and Fabrication of Terahertz Metallic Gratings on a Two-Wire Waveguide
In this study, we present the design, fabrication and experimental characterization of waveguide-integrated gratings operating at THz frequencie
Dimension Reduction in the Context of Structured Deformations
In this paper we apply both the procedure of dimension reduction and the incorporation of structured deformations to a three-dimensional continuum in the form of a thinning domain. We apply the two processes one after the other, exchanging the order, and so obtain for each order both a relaxed bulk and a relaxed interfacial energy. Our implementation requires some substantial modifications of the two relaxation procedures. For the specific choice of an initial energy including only the surface term, we compute the energy densities explicitly and show that they are the same, independent of the order of the relaxation processes. Moreover, we compare our explicit results with those obtained when the limiting process of dimension reduction and of passage to the structured deformation is carried out at the same time. We finally show that, in a portion of the common domain of the relaxed energy densities, the simultaneous procedure gives an energy strictly lower than that obtained in the two-step relaxations
Hanbury Brown and Twiss Correlations of Anderson Localized Waves
When light waves propagate through disordered photonic lattices, they can
eventually become localized due to multiple scattering effects. Here we show
experimentally that while the evolution and localization of the photon density
distribution is similar in the two cases of diagonal and off-diagonal disorder,
the density-density correlation carries a distinct signature of the type of
disorder. We show that these differences reflect a symmetry in the spectrum and
eigenmodes that exists in off-diagonally disordered lattices but is absent in
lattices with diagonal disorder.Comment: 4 pages, 3 figures, comments welcom
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