43 research outputs found
Monte Carlo studies of the square Ising model with next-nearest-neighbor interactions
We apply a new entropic scheme to study the critical behavior of the
square-lattice Ising model with nearest- and next-nearest-neighbor
antiferromagnetic interactions. Estimates of the present scheme are compared
with those of the Metropolis algorithm. We consider interactions in the range
where superantiferromagnetic (SAF) order appears at low temperatures. A recent
prediction of a first-order transition along a certain range (0.5-1.2) of the
interaction ratio is examined by generating accurate data
for large lattices at a particular value of the ratio . Our study does
not support a first-order transition and a convincing finite-size scaling
analysis of the model is presented, yielding accurate estimates for all
critical exponents for R=1 . The magnetic exponents are found to obey ``weak
universality'' in accordance with a previous conjecture.Comment: 9 pages, 7 figures, Proceedings of the third NEXT Sigma Phi
International Conference, kolymbari, Greece (2005
Local symmetry dynamics in one-dimensional aperiodic lattices
A unifying description of lattice potentials generated by aperiodic
one-dimensional sequences is proposed in terms of their local reflection or
parity symmetry properties. We demonstrate that the ranges and axes of local
reflection symmetry possess characteristic distributional and dynamical
properties which can be determined for every aperiodic binary lattice. A
striking aspect of such a property is given by the return maps of sequential
spacings of local symmetry axes, which typically traverse few-point symmetry
orbits. This local symmetry dynamics allows for a classification of inherently
different aperiodic lattices according to fundamental symmetry principles.
Illustrating the local symmetry distributional and dynamical properties for
several representative binary lattices, we further show that the renormalized
axis spacing sequences follow precisely the particular type of underlying
aperiodic order. Our analysis thus reveals that the long-range order of
aperiodic lattices is characterized in a compellingly simple way by its local
symmetry dynamics.Comment: 15 pages, 12 figure
Local symmetries and perfect transmission in aperiodic photonic multilayers
We develop a classification of perfectly transmitting resonances occuring in
effectively one-dimensional optical media which are decomposable into locally
reflection symmetric parts. The local symmetries of the medium are shown to
yield piecewise translation-invariant quantities, which are used to distinguish
resonances with arbitrary field profile from resonances following the medium
symmetries. Focusing on light scattering in aperiodic multilayer structures, we
demonstrate this classification for representative setups, providing insight
into the origin of perfect transmission. We further show how local symmetries
can be utilized for the design of optical devices with perfect transmission at
prescribed energies. Providing a link between resonant scattering and local
symmetries of the underlying medium, the proposed approach may contribute to
the understanding of optical response in complex systems.Comment: 8 pages, 4 figure
Invariant currents in lossy acoustic waveguides with complete local symmetry
We implement the concept of complete local symmetry in lossy acoustic
waveguides. Despite the presence of losses, the existence of a spatially
invariant current is shown theoretically and observed experimentally. We
demonstrate how this invariant current leads to the generalization of the Bloch
and parity theorems for lossy systems defining a mapping of the pressure field
between symmetry related spatial domains. Using experimental data we verify
this mapping with remarkable accuracy. For the performed experiment we employ a
construction technique based on local symmetries which allows the design of
setups with prescribed perfect transmission resonances in the lossless case.
Our results reveal the fundamental role of symmetries in restricted spatial
domains and clearly indicate that completely locally symmetric devices
constitute a promising class of setups, regarding the manipulation of wave
propagation.Comment: 11 pages, 5 figure