786 research outputs found
Polydispersed Granular Chains: From Long-lived Chaotic Anderson-like Localization to Energy Equipartition
We investigate the dynamics of highly polydispersed finite granular chains.
From the spatio-spectral properties of small vibrations, we identify which
particular single-particle displacements lead to energy localization. Then, we
address a fundamental question: Do granular nonlinearities lead to chaotic
dynamics and if so, does chaos destroy this energy localization? Our numerical
simulations show that for moderate nonlinearities, although the overall system
behaves chaotically, it can exhibit long lasting energy localization for
particular single particle excitations. On the other hand, for sufficiently
strong nonlinearities, connected with contact breaking, the granular chain
reaches energy equipartition and an equilibrium chaotic state, independent of
the initial position excitation
Wave Propagation in a Strongly Nonlinear Locally Resonant Granular Crystal
In this work, we study the wave propagation in a recently proposed acoustic
structure, the locally resonant granular crystal. This structure is composed of
a one-dimensional granular crystal of hollow spherical particles in contact,
containing linear resonators. The relevant model is presented and examined
through a combination of analytical approximations (based on ODE and nonlinear
map analysis) and of numerical results. The generic dynamics of the system
involves a degradation of the well-known traveling pulse of the standard
Hertzian chain of elastic beads. Nevertheless, the present system is richer, in
that as the primary pulse decays, secondary ones emerge and eventually
interfere with it creating modulated wavetrains. Remarkably, upon suitable
choices of parameters, this interference "distills" a weakly nonlocal solitary
wave (a "nanopteron"). This motivates the consideration of such nonlinear
structures through a separate Fourier space technique, whose results suggest
the existence of such entities not only with a single-side tail, but also with
periodic tails on both ends. These tails are found to oscillate with the
intrinsic oscillation frequency of the out-of-phase motion between the outer
hollow bead and its internal linear attachment
Dark Breathers in Granular Crystals
We present a study of the existence, stability and bifurcation structure of
families of dark breathers in a one-dimensional uniform chain of spherical
beads under static load. A defocus- ing nonlinear Schrodinger equation (NLS) is
derived for frequencies that are close to the edge of the phonon band and is
used to construct targeted initial conditions for numerical computations.
Salient features of the system include the existence of large amplitude
solutions that bifurcate with the small amplitude solutions described by the
NLS equation, and the presence of a nonlinear instability that, to the best of
the authors knowledge, has not been observed in classical Fermi- Pasta-Ulam
lattices. Finally, it is also demonstrated that these dark breathers can be
detected in a physically realistic way by merely actuating the ends of an
initially at rest chain of beads and inducing destructive interference between
their signals
Non-Hermitian Acoustic Metamaterials: the role of Exceptional Points in sound absorption
Effective non-Hermitian Hamiltonians are obtained to describe coherent
perfect absorbing and lasing boundary conditions. PT -symmetry of the
Hamiltonians enables to design configurations which perfectly absorb at
multiple frequencies. Broadened and flat perfect absorption is predicted at the
exceptional point of PT -symmetry breaking while, for a particular case,
absorption is enhanced with the use of gain. The aforementioned phenomena are
illustrated for acoustic scattering through Helmholtz resonators revealing how
tailoring the non-Hermiticity of acoustic metamaterials leads to novel
mechanisms for enhanced absorption
Matter-wave solitons of collisionally inhomogeneous condensates
We investigate the dynamics of matter-wave solitons in the presence of a
spatially varying atomic scattering length and nonlinearity. The dynamics of
bright and dark solitary waves is studied using the corresponding
Gross-Pitaevskii equation. The numerical results are shown to be in very good
agreement with the predictions of the effective equations of motion derived by
adiabatic perturbation theory. The spatially dependent nonlinearity leads to a
gravitational potential that allows to influence the motion of both fundamental
as well as higher order solitons.Comment: 19 pages, 4 figure
Avoiding Infrared Catastrophes in Trapped Bose-Einstein Condensates
This paper is concerned with the long wavelength instabilities (infrared
catastrophes) occurring in Bose-Einstein condensates (BECs). We examine the
modulational instability in ``cigar-shaped'' (1D) attractive BECs and the
transverse instability of dark solitons in ``pancake'' (2D) repulsive BECs. We
suggest mechanisms, and give explicit estimates, on how to ``engineer'' the
trapping conditions of the condensate to avoid such instabilities: the main
result being that a tight enough trapping potential suppresses the
instabilities present in the homogeneous limit. We compare the obtained
estimates with numerical results and we highlight the relevant regimes of
dynamical behavior
Defect Modes in One-Dimensional Granular Crystals
We study the vibrational spectra of one-dimensional statically compressed
granular crystals (arrays of elastic particles in contact) containing defects.
We focus on the prototypical settings of one or two spherical defects
(particles of smaller radii) interspersed in a chain of larger uniform
spherical particles. We measure the near-linear frequency spectrum within the
spatial vicinity of the defects, and identify the frequencies of the localized
defect modes. We compare the experimentally determined frequencies with those
obtained by numerical eigen-analysis and by analytical expressions based on
few-site considerations. We also present a brief numerical and experimental
example of the nonlinear generalization of a single-defect localized mode
Transversal-rotational and zero group velocity modes in tunable magneto-granular phononic crystals
We report on the design and operation of a 1D magneto-granular phononic
crystal composed of a chain of steel spherical beads on top of permanent
magnets. The magnetic field of the permanent magnets induces forces in the
granular structure. By changing its strength, we can tune the dynamic response
of the granular structure. We present experimental results with evidence of
coupled transversal-rotational modes, and zero group velocities modes. These
observations are well supported by a proposed model taking into account the
mechanical coupling between the beads and the magnets by linear stiffnesses and
including all degrees of freedom in translations and rotations
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