4,369 research outputs found
Magnetic Susceptibility of an integrable anisotropic spin ladder system
We investigate the thermodynamics of a spin ladder model which possesses a
free parameter besides the rung and leg couplings. The model is exactly solved
by the Bethe Ansatz and exhibits a phase transition between a gapped and a
gapless spin excitation spectrum. The magnetic susceptibility is obtained
numerically and its dependence on the anisotropy parameter is determined. A
connection with the compounds KCuCl3, Cu2(C5H12N2)2Cl4 and (C5H12N)2CuBr4 in
the strong coupling regime is made and our results for the magnetic
susceptibility fit the experimental data remarkably well.Comment: 12 pages, 12 figures included, submitted to Phys. Rev.
Capillary rise of a liquid between two vertical plates making a small angle.
The penetration of a wetting liquid in the narrow gap between two vertical plates making a small angle is analyzed in the framework of the lubrication approximation. At the beginning of the process, the liquid rises independently at different distances from the line of intersection of the plates except in a small region around this line where the effect of the gravity is negligible. The maximum height of the liquid initially increases as the cubic root of time and is attained at a point that reaches the line of intersection only after a certain time. At later times, the motion of the liquid is confined to a thin layer around the line of intersection whose height increases as the cubic root of time and whose thickness decreases as the inverse of the cubic root of time. The evolution of the liquid surface is computed numerically and compared with the results of a simple experiment
Energetics and dynamics of simple impulsive solar flares
Flare energetics and dynamics were studied using observations of simple impulsive spike bursts. A large, homogeneous set of events was selected to enable the most definite tests possible of competing flare models, in the absence of spatially resolved observations. The emission mechanisms and specific flare models that were considered in this investigation are described, and the derivations of the parameters that were tested are presented. Results of the correlation analysis between soft and hard X-ray energetics are also presented. The ion conduction front model and tests of that model with the well-observed spike bursts are described. Finally, conclusions drawn from this investigation and suggestions for future studies are discussed
The Dynamics of the One-Dimensional Delta-Function Bose Gas
We give a method to solve the time-dependent Schroedinger equation for a
system of one-dimensional bosons interacting via a repulsive delta function
potential. The method uses the ideas of Bethe Ansatz but does not use the
spectral theory of the associated Hamiltonian
Universality Class of the Reversible-Irreversible Transition in Sheared Suspensions
Collections of non-Brownian particles suspended in a viscous fluid and
subjected to oscillatory shear at very low Reynolds number have recently been
shown to exhibit a remarkable dynamical phase transition separating reversible
from irreversible behaviour as the strain amplitude or volume fraction are
increased. We present a simple model for this phenomenon, based on which we
argue that this transition lies in the universality class of the conserved DP
models or, equivalently, the Manna model. This leads to predictions for the
scaling behaviour of a large number of experimental observables. Non-Brownian
suspensions under oscillatory shear may thus constitute the first experimental
realization of an inactive-active phase transition which is not in the
universality class of conventional directed percolation.Comment: 4 pages, 2 figures, final versio
One-dimensional anyons with competing -function and derivative -function potentials
We propose an exactly solvable model of one-dimensional anyons with competing
-function and derivative -function interaction potentials. The
Bethe ansatz equations are derived in terms of the -particle sector for the
quantum anyonic field model of the generalized derivative nonlinear
Schr\"{o}dinger equation. This more general anyon model exhibits richer physics
than that of the recently studied one-dimensional model of -function
interacting anyons. We show that the anyonic signature is inextricably related
to the velocities of the colliding particles and the pairwise dynamical
interaction between particles.Comment: 9 pages, 2 figures, minor changes, references update
Navier-Stokes equations on the flat cylinder with vorticity production on the boundary
We study the two-dimensional Navier-Stokes system on a flat cylinder with the
usual Dirichlet boundary conditions for the velocity field u. We formulate the
problem as an infinite system of ODE's for the natural Fourier components of
the vorticity, and the boundary conditions are taken into account by adding a
vorticity production at the boundary. We prove equivalence to the original
Navier-Stokes system and show that the decay of the Fourier modes is
exponential for any positive time in the periodic direction, but it is only
power-like in the other direction.Comment: 25 page
Evidence of discrete scale invariance in DLA and time-to-failure by canonical averaging
Discrete scale invariance, which corresponds to a partial breaking of the
scaling symmetry, is reflected in the existence of a hierarchy of
characteristic scales l0, c l0, c^2 l0,... where c is a preferred scaling ratio
and l0 a microscopic cut-off. Signatures of discrete scale invariance have
recently been found in a variety of systems ranging from rupture, earthquakes,
Laplacian growth phenomena, ``animals'' in percolation to financial market
crashes. We believe it to be a quite general, albeit subtle phenomenon. Indeed,
the practical problem in uncovering an underlying discrete scale invariance is
that standard ensemble averaging procedures destroy it as if it was pure noise.
This is due to the fact, that while c only depends on the underlying physics,
l0 on the contrary is realisation-dependent. Here, we adapt and implement a
novel so-called ``canonical'' averaging scheme which re-sets the l0 of
different realizations to approximately the same value. The method is based on
the determination of a realization-dependent effective critical point obtained
from, e.g., a maximum susceptibility criterion. We demonstrate the method on
diffusion limited aggregation and a model of rupture.Comment: 14 pages, 6 figures, in press in Int. J. Mod. Phys.
Kolmogorov's law for two-dimensional electron-magnetohydrodynamic turbulence
The analogue of the Kolmogorov's four-fifths law is derived for
two-dimensional, homogeneous, isotropic EMHD turbulence in the energy cascade
inertial range. Direct numerical simulations for the freely decaying case show
that this relation holds true for different values of the adimensional electron
inertial length scale, . The energy spectrum is found to be close to the
expected Kolmogorov spectrum.Comment: 9 pages RevTeX, 3 PostScript figure
Excitation of inertial modes in a closed grid turbulence experiment under rotation
We report an experimental study of the decay of grid-generated turbulence in
a confined geometry submitted to a global rotation. Turbulence is generated by
rapidly towing a grid in a parallelepipedic water tank. The velocity fields of
a large number of independent decays are measured in a vertical plane parallel
to the rotation axis using a corotating Particle Image Velocimetry system. We
first show that, when a "simple" grid is used, a significant amount of the
kinetic energy (typically 50%) is stored in a reproducible flow composed of
resonant inertial modes. The spatial structure of those inertial modes,
extracted by band-pass filtering, is found compatible with the numerical
results of Maas [Fluid Dyn. Res. 33, 373 (2003)]. The possible coupling between
these modes and turbulence suggests that turbulence cannot be considered as
freely decaying in this configuration. Finally, we demonstrate that these
inertial modes may be significantly reduced (down to 15% of the total energy)
by adding a set of inner tanks attached to the grid. This suggests that it is
possible to produce an effectively freely decaying rotating turbulence in a
confined geometry
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