6,511 research outputs found
Quantum properties of a non-Gaussian state in the large-N approximation
We study the properties of a non-Gaussian density matrix for a O(N) scalar
field in the context of the incomplete description picture. This is of
relevance for studies of decoherence and entropy production in quantum field
theory. In particular, we study how the inclusion of the simplest non-Gaussian
correlator in the set of measured observables modifies the effective (Gaussian)
description one can infer from the knowledge of the two-point functions only.
We compute exactly the matrix elements of the non-Gaussian density matrix at
leading order in a 1/N-expansion. This allows us to study the quantum
properties (purity, entropy, coherence) of the corresponding state for
arbitrarily strong nongaussianity. We find that if the Gaussian and the
non-Gaussian observers essentially agree concerning quantum purity or
correlation entropy, their conclusion can significantly differ for other, more
detailed aspects such as the degree of quantum coherence of the system.Comment: 14 pages, 7 figures. Published version (Phys. Rev. D, minor
corrections
Limits of flexural wave absorption by open lossy resonators: reflection and transmission problems
The limits of flexural wave absorption by open lossy resonators are
analytically and numerically reported in this work for both the reflection and
transmission problems. An experimental validation for the reflection problem is
presented. The reflection and transmission of flexural waves in 1D resonant
thin beams are analyzed by means of the transfer matrix method. The hypotheses,
on which the analytical model relies, are validated by experimental results.
The open lossy resonator, consisting of a finite length beam thinner than the
main beam, presents both energy leakage due to the aperture of the resonators
to the main beam and inherent losses due to the viscoelastic damping. Wave
absorption is found to be limited by the balance between the energy leakage and
the inherent losses of the open lossy resonator. The perfect compensation of
these two elements is known as the critical coupling condition and can be
easily tuned by the geometry of the resonator. On the one hand, the scattering
in the reflection problem is represented by the reflection coefficient. A
single symmetry of the resonance is used to obtain the critical coupling
condition. Therefore the perfect absorption can be obtained in this case. On
the other hand, the transmission problem is represented by two eigenvalues of
the scattering matrix, representing the symmetric and anti-symmetric parts of
the full scattering problem. In the geometry analyzed in this work, only one
kind of symmetry can be critically coupled, and therefore, the maximal
absorption in the transmission problem is limited to 0.5. The results shown in
this work pave the way to the design of resonators for efficient flexural wave
absorption
Effects of geometrical nonlinearities on the acoustic black hole effect
International audienceThe Acoustic Black Hole effect (ABH) is a passive vibration damping technique without added mass based on flexural waves properties in thin structures with variable thickness. The usual implementation on plates is a region where the thickness is reduced with a power law profile, covered with a visco-elastic layer. The inhomogoneity induces a decrease of the wave speed and an increase of the amplitude in the small thickness region, which makes the energy dissipation more efficient due to the absorbing layer. The wave amplitude in the ABH easily reaches the plate thickness and is the origin of geometrical nonlinearities. These nonlin-earities can generate coupling between linear beam eigenmodes of the structure and induce energy transfer between low and high frequency regime. This phenomenon may be used to increase the efficiency of the ABH treatment in the low frequency regime where it is usually inefficient. An experimental investigation shows that the ABH termination displays a nonlinear behaviour and allows for modal coupling. A strongly nonlinear regime can also be observed, which is associated with Wave Turbulence. A model of nonlinear ABH beam as von Kármán plate of variable thickness and a modal resolution of the problem confirm the observed effects and gives more insights on these results
On the Langevin description of nonequilibrium quantum fields
We consider the non-equilibrium dynamics of a real quantum scalar field. We
show the formal equivalence of the exact evolution equations for the
statistical and spectral two-point functions with a fictitious Langevin process
and examine the conditions under which a local Markovian dynamics is a valid
approximation. In quantum field theory, the memory kernel and the noise
correlator typically exhibit long time power laws and are thus highly
non-local, thereby questioning the possibility of a local description. We show
that despite this fact, there is a finite time range during which a local
description is accurate. This requires the theory to be (effectively) weakly
coupled. We illustrate the use of such a local description for studies of
decoherence and entropy production in quantum field theory.Comment: 15 pages, 3 figures, references added, typos corrected. To appear in
Phys. Rev.
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