14,390 research outputs found
Face pairing graphs and 3-manifold enumeration
The face pairing graph of a 3-manifold triangulation is a 4-valent graph
denoting which tetrahedron faces are identified with which others. We present a
series of properties that must be satisfied by the face pairing graph of a
closed minimal P^2-irreducible triangulation. In addition we present
constraints upon the combinatorial structure of such a triangulation that can
be deduced from its face pairing graph. These results are then applied to the
enumeration of closed minimal P^2-irreducible 3-manifold triangulations,
leading to a significant improvement in the performance of the enumeration
algorithm. Results are offered for both orientable and non-orientable
triangulations.Comment: 30 pages, 57 figures; v2: clarified some passages and generalised the
final theorem to the non-orientable case; v3: fixed a flaw in the proof of
the conical face lemm
Perfect tag identification protocol in RFID networks
Radio Frequency IDentification (RFID) systems are becoming more and more
popular in the field of ubiquitous computing, in particular for objects
identification. An RFID system is composed by one or more readers and a number
of tags. One of the main issues in an RFID network is the fast and reliable
identification of all tags in the reader range. The reader issues some queries,
and tags properly answer. Then, the reader must identify the tags from such
answers. This is crucial for most applications. Since the transmission medium
is shared, the typical problem to be faced is a MAC-like one, i.e. to avoid or
limit the number of tags transmission collisions. We propose a protocol which,
under some assumptions about transmission techniques, always achieves a 100%
perfomance. It is based on a proper recursive splitting of the concurrent tags
sets, until all tags have been identified. The other approaches present in
literature have performances of about 42% in the average at most. The
counterpart is a more sophisticated hardware to be deployed in the manufacture
of low cost tags.Comment: 12 pages, 1 figur
A dual view of the 3d Heisenberg model and the abelian projection
The Heisenberg model in 3d is studied from a dual point of view. It is shown
that it can have vortex configurations, carrying a conserved charge(U(1)
symmetry). Vortices condens in the disordered phase. A disorder parameter
\leftangle\mu\rightangle is defined dual to the magnetization \leftangle\vec
n\rightangle, which signals condensation of vortices, i.e. spontaneous
breaking of the dual U(1) symmetry. This study sheds light on the procedure
known as abelian projection in non abelian gauge theories.Comment: LateX, 15 pages, 3 figure
Local Structure Analysis in Liquid Water
Within the framework of density functional theory, the inclusion of exact
exchange and non-local van der Waals/dispersion (vdW) interactions is crucial
for predicting a microscopic structure of ambient liquid water that
quantitatively agrees with experiment. In this work, we have used the local
structure index (LSI) order parameter to analyze the local structure in such
highly accurate liquid water. At ambient conditions, the LSI
probability distribution, P(), was unimodal with most water molecules
characterized by more disordered high-density-like local environments. With
thermal excitations removed, the resultant bimodal P() in the inherent
potential energy surface (IPES) exhibited a 3:1 ratio between high- and
low-density-like molecules, with the latter forming small connected clusters
amid the predominant population. By considering the spatial correlations and
hydrogen bond network topologies water molecules with the same LSI
identities, we demonstrate that the signatures of the experimentally observed
low- (LDA) and high-density (HDA) amorphous phases of ice are present in the
IPES of ambient liquid water. Analysis of the LSI autocorrelation function
uncovered a persistence time of 4 ps---a finding consistent with the
fact that natural thermal fluctuations are responsible for transitions between
these distinct yet transient local aqueous environments in ambient liquid
water.Comment: 12 pages, 6 figure
Gravity duals of supersymmetric gauge theories on three-manifolds
We study gravity duals to a broad class of N=2 supersymmetric gauge theories
defined on a general class of three-manifold geometries. The gravity
backgrounds are based on Euclidean self-dual solutions to four-dimensional
gauged supergravity. As well as constructing new examples, we prove in general
that for solutions defined on the four-ball the gravitational free energy
depends only on the supersymmetric Killing vector, finding a simple closed
formula when the solution has U(1) x U(1) symmetry. Our result agrees with the
large N limit of the free energy of the dual gauge theory, computed using
localization. This constitutes an exact check of the gauge/gravity
correspondence for a very broad class of gauge theories with a large N limit,
defined on a general class of background three-manifold geometries.Comment: 74 pages, 2 figures; v2: minor change
Operator Counting and Eigenvalue Distributions for 3D Supersymmetric Gauge Theories
We give further support for our conjecture relating eigenvalue distributions
of the Kapustin-Willett-Yaakov matrix model in the large N limit to numbers of
operators in the chiral ring of the corresponding supersymmetric
three-dimensional gauge theory. We show that the relation holds for
non-critical R-charges and for examples with {\mathcal N}=2 instead of
{\mathcal N}=3 supersymmetry where the bifundamental matter fields are
nonchiral. We prove that, for non-critical R-charges, the conjecture is
equivalent to a relation between the free energy of the gauge theory on a three
sphere and the volume of a Sasaki manifold that is part of the moduli space of
the gauge theory. We also investigate the consequences of our conjecture for
chiral theories where the matrix model is not well understood.Comment: 27 pages + appendices, 5 figure
Multidomain switching in the ferroelectric nanodots
Controlling the polarization switching in the ferroelectric nanocrystals,
nanowires and nanodots has an inherent specificity related to the emergence of
depolarization field that is associated with the spontaneous polarization. This
field splits the finite-size ferroelectric sample into polarization domains.
Here, based on 3D numerical simulations, we study the formation of 180 polarization domains in a nanoplatelet, made of uniaxial ferroelectric
material, and show that in addition to the polarized monodomain state, the
multidomain structures, notably of stripe and cylindrical shapes, can arise and
compete during the switching process. The multibit switching protocol between
these configurations may be realized by temperature and field variations
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