631 research outputs found
Interface Unbinding in Structured Wedges
The unbinding properties of an interface near structured wedges are
investigated by discrete models with short range interactions. The calculations
demonstrate that interface unbinding take place in two stages: ) a
continuous filling--like transition in the pure wedge--like parts of the
structure; ) a conclusive discontinuous unbinding. In 2 an exact
transfer matrix approach allows to extract the whole interface phase diagram
and the precise mechanism at the basis of the phenomenon. The Metropolis Monte
Carlo simulations performed in 3 reveal an analogous behavior. The emerging
scenario allows to shed new light onto the problem of wetting of geometrically
rough walls.Comment: 5 pages, 5 figures, to appear in Phys. Rev.
Ground State Wave Function of the Schr\"odinger Equation in a Time-Periodic Potential
Using a generalized transfer matrix method we exactly solve the Schr\"odinger
equation in a time periodic potential, with discretized Euclidean space-time.
The ground state wave function propagates in space and time with an oscillating
soliton-like wave packet and the wave front is wedge shaped. In a statistical
mechanics framework our solution represents the partition sum of a directed
polymer subjected to a potential layer with alternating (attractive and
repulsive) pinning centers.Comment: 11 Pages in LaTeX. A set of 2 PostScript figures available upon
request at [email protected] . Physical Review Letter
A Simulation Model Outline for the Hungarian Forest Sector
The model presented in this paper describes the structure of the Hungarian forest sector. The planning of the sector at a national and company level as well as the mechanism of regulation concerning production, investments, and consumption are also investigated and the exports and imports linked.
One of the most important objectives is to create this model in order to study the behavior of the system so as to aid the decision making both in strategic and tactical areas. Apart from forestry the model also includes the wood processing activities
Renormalon disappearance in Borel sum of the 1/N expansion of the Gross-Neveu model mass gap
The exact mass gap of the O(N) Gross-Neveu model is known, for arbitrary ,
from non-perturbative methods. However, a "naive" perturbative expansion of the
pole mass exhibits an infinite set of infrared renormalons at order 1/N,
formally similar to the QCD heavy quark pole mass renormalons, potentially
leading to large perturbative ambiguities. We examine the
precise vanishing mechanism of such infrared renormalons, which avoids this
(only apparent)contradiction, and operates without need of (Borel) summation
contour prescription, usually preventing unambiguous separation of perturbative
contributions. As a consequence we stress the direct Borel summability of the
(1/N) perturbative expansion of the mass gap. We briefly speculate on a
possible similar behaviour of analogous non-perturbative QCD quantities.Comment: 16 pp., 1 figure. v2: a few paragraphs and one appendix added, title
and abstract slightly changed, essential results unchange
Transient Pattern Formation in an Active Matter Contact Poisoning Model
One of the most notable features in repulsive particle based active matter
systems is motility-induced-phase separation (MIPS) where a dense, often
crystalline phase coexists with a low density fluid. In most active matter
studies, the activity is kept constant as a function of time; however, there
are many examples of active systems in which individual particles transition
from living or moving to dead or nonmotile due to lack of fuel, infection, or
poisoning. Here we consider an active matter particle system at densities where
MIPS does not occur. When we add a small number of infected particles that can
effectively poison other particles, rendering them nonmotile, we find a rich
variety of time dependent pattern formation, including MIPS, a wetting phase,
and a fragmented state formed when mobile particles plow through an nonmotile
packing. We map out the patterns as a function of time scaled by the duration
of the epidemic, and show that the pattern formation is robust for a wide range
of poisoning rates and activity levels. We also show that pattern formation
does not occur in a random death model, but requires the promotion of
nucleation by contact poisoning. Our results should be relevant to biological
and active matter systems where there is some form of poisoning, death, or
transition to nonmotility.Comment: 7 pages, 6 figure
Network formation of tissue cells via preferential attraction to elongated structures
Vascular and non-vascular cells often form an interconnected network in
vitro, similar to the early vascular bed of warm blooded embryos. Our
time-lapse recordings show that the network forms by extending sprouts, i.e.,
multicellular linear segments. To explain the emergence of such structures, we
propose a simple model of preferential attraction to stretched cells. Numerical
simulations reveal that the model evolves into a quasi-stationary pattern
containing linear segments, which interconnect above the critical volume
fraction of 0.2. In the quasi-stationary state the generation of new branches
offset the coarsening driven by surface tension. In agreement with empirical
data, the characteristic size of the resulting polygonal pattern is
density-independent within a wide range of volume fractions
A Monopole-Antimonopole Solution of the SU(2) Yang-Mills-Higgs Model
As shown by Taubes, in the Bogomol'nyi-Prasad-Sommerfield limit the SU(2)
Yang-Mills-Higgs model possesses smooth finite energy solutions, which do not
satisfy the first order Bogomol'nyi equations. We construct numerically such a
non-Bogomol'nyi solution, corresponding to a monopole-antimonopole pair, and
extend the construction to finite Higgs potential.Comment: 11 pages, including 4 eps figures, LaTex format using RevTe
An indole alkaloid from Strychnos erichsonii
Le premier alcaloïde indolique de type vobasine rencontré dans les #Loganiaceae a été isolé des écorces de #Strychnos erichsonii, récoltées en Guyane Française. Sa structure confirmée par cristallographie Rx. (Résumé d'auteur
Integrability in Theories with Local U(1) Gauge Symmetry
Using a recently developed method, based on a generalization of the zero
curvature representation of Zakharov and Shabat, we study the integrability
structure in the Abelian Higgs model. It is shown that the model contains
integrable sectors, where integrability is understood as the existence of
infinitely many conserved currents. In particular, a gauge invariant
description of the weak and strong integrable sectors is provided. The
pertinent integrability conditions are given by a U(1) generalization of the
standard strong and weak constraints for models with two dimensional target
space. The Bogomolny sector is discussed, as well, and we find that each
Bogomolny configuration supports infinitely many conserved currents. Finally,
other models with U(1) gauge symmetry are investigated.Comment: corrected typos, version accepted in J. Phys.
- …