319 research outputs found
Fast and slow light in zig-zag microring resonator chains
We analyze fast and slow light transmission in a zig-zag microring resonator
chain. This novel device permits the operation in both regimes. In the
superluminal case, a new ubiquitous light transmission effect is found whereby
the input optical pulse is reproduced in an almost simultaneous manner at the
various system outputs. When the input carrier is tuned to a different
frequency, the system permits to slow down the propagating optical signal.
Between these two extreme cases, the relative delay can be tuned within a broad
range
Coupled-Mode Theory of Field Enhancement in Complex Metal Nanostructures
We describe a simple yet rigorous theoretical model capable of analytical
estimation of plasmonic field enhancement in complex metal structures. We show
that one can treat the complex structures as coupled multi-pole modes with
highest enhancements obtained due to superposition of high order modes in small
particles. The model allows one to optimize the structures for the largest
possible field enhancements, which depends on the quality factor Q of the metal
and can be as high as Q^2 for two spherical particles. The "hot spot" can occur
either in the nano-gaps between the particles or near the smaller particles. We
trace the optimum field enhancement mechanism to the fact that the extended
dipole modes of larger particles act as the efficient antennas while the modes
in the gaps or near the smaller particles act as the compact sub-wavelength
cavities. We also show how easily our approach can be extended to incorporate
large numbers of particles in intricate arrangements.Comment: 23 pages, 7 figure
Strain-free Ge/GeSiSn quantum cascade lasers based on L-valley intersubband transitions
The authors propose a Ge/Ge0.76Si0.19Sn0.05 quantum cascade laser using intersubband transitions at L valleys of the conduction band which has a “clean” offset of150 meV situated below other energy valleys (Γ,X). The entire structure is strain-free because the lattice-matched Ge and Ge0.76Si0.19Sn0.05 layers are to be grown on a relaxed Ge buffer layer on a Si substrate. Longer lifetimes due to the weaker scattering of nonpolar optical phonons reduce the threshold current and potentially lead to room temperature operation
Semi-analytic method for slow light photonic crystal waveguide design
We present a semi-analytic method to calculate the dispersion curves and the
group velocity of photonic crystal waveguide modes in two-dimensional
geometries. We model the waveguide as a homogenous strip, surrounded by
photonic crystal acting as diffracting mirrors. Following conventional
guided-wave optics, the properties of the photonic crystal waveguide may be
calculated from the phase upon propagation over the strip and the phase upon
reflection. The cases of interest require a theory including the specular order
and one other diffracted reflected order. The computational advantages let us
scan a large parameter space, allowing us to find novel types of solutions.Comment: Accepted by Photonics and Nanostructures - Fundamentals and
Application
Band splitting and Modal Dispersion induced by Symmetry braking in Coupled-Resonator Slow-Light Waveguide Structures
We study the dispersion relations in slow-light waveguide structures
consisting of coupled microdisk resonators. A group theoretical analysis of the
symmetry properties of the propagating modes reveals an interesting phenomenon:
The degeneracy of the CW and CCW rotating modes is removed, giving rise to two
distinct transmission bands. This effect induces symmetry-based dispersion
which may limit usable bandwidth of such structures. The properties of this
band splitting and its impact on CROW performance for optical communications
are studied in detail
Observaton of tunneling of slow and fast electromagnetic modes in coupled periodic waveguides
We report the experimental observation of tunneling of slow and fast electromagnetic modes in coupled periodic waveguides shifted longitudinally by half of modulation period. According to the symmetry analysis, such a coupler supports two electromagnetic modes with exactly matched slow or fast group velocities but different phase velocities for frequencies close to the edge of the photonic band. We confirm the predicted properties of the modes by directly extracting their dispersion and group velocities from the near-field measurements using specialized Bloch-wave spectral analysis method.This work was supported by the Australian Research
Council
Flat-band ferromagnetism in quantum dot superlattices
Possibility of flat-band ferromagnetism in quantum dot arrays is
theoretically discussed. By using a quantum dot as a building block, quantum
dot superlattices are possible. We consider dot arrays on Lieb and kagome
lattices known to exhibit flat band ferromagnetism. By performing an exact
diagonalization of the Hubbard Hamiltonian, we calculate the energy difference
between the ferromagnetic ground state and the paramagnetic excited state, and
discuss the stability of the ferromagnetism against the second nearest neighbor
transfer. We calculate the dot-size dependence of the energy difference in a
dot model and estimate the transition temperature of the
ferromagnetic-paramagnetic transition which is found to be accessible within
the present fabrication technology. We point out advantages of semiconductor
ferromagnets and suggest other interesting possibilities of electronic
properties in quantum dot superlattices.Comment: 15 pages, 7 figures (low resolution). High-resolution figures are
available at
http://www.brl.ntt.co.jp/people/tamura/Research/PublicationPapers.htm
Phaseless VLBI mapping of compact extragalactic radio sources
The problem of phaseless aperture synthesis is of current interest in
phase-unstable VLBI with a small number of elements when either the use of
closure phases is not possible (a two-element interferometer) or their quality
and number are not enough for acceptable image reconstruction by standard
adaptive calibration methods. Therefore, we discuss the problem of unique image
reconstruction only from the spectrum magnitude of a source. We suggest an
efficient method for phaseless VLBI mapping of compact extragalactic radio
sources. This method is based on the reconstruction of the spectrum magnitude
for a source on the entire UV plane from the measured visibility magnitude on a
limited set of points and the reconstruction of the sought-for image of the
source by Fienup's method from the spectrum magnitude reconstructed at the
first stage. We present the results of our mapping of the extragalactic radio
source 2200 +420 using astrometric and geodetic observations on a global VLBI
array. Particular attention is given to studying the capabilities of a
two-element interferometer in connection with the putting into operation of a
Russian-made radio interferometer based on Quasar RT-32 radio telescopes.Comment: 21 pages, 6 figure
- …