Your search keyword '"Randoux , Stéphane"' showing total 6 results

1. Nonlinear dispersion relation in integrable turbulence.

Author

Tikan, Alexey, Bonnefoy, Félicien, Ducrozet, Guillaume, Prabhudesai, Gaurav, Michel, Guillaume, Cazaubiel, Annette, Falcon, Éric, Copie, Francois, Randoux, Stéphane, and Suret, Pierre

Subjects

DISPERSION relations, NONLINEAR Schrodinger equation, ROGUE waves, TURBULENCE, NONLINEAR waves, WAVENUMBER

Abstract

We investigate numerically and experimentally the concept of nonlinear dispersion relation (NDR) in the context of partially coherent waves propagating in a one-dimensional water tank. The nonlinear random waves have a narrow-bandwidth Fourier spectrum and are described at leading order by the one-dimensional nonlinear Schrödinger equation. The problem is considered in the framework of integrable turbulence in which solitons play a key role. By using a limited number of wave gauges, we accurately measure the NDR of the slowly varying envelope of the deep-water waves. This enables the precise characterization of the frequency shift and the broadening of the NDR while also revealing the presence of solitons. Moreover, our analysis shows that the shape and the broadening of the NDR provides signatures of the deviation from integrable turbulence that is induced by high order effects in experiments. We also compare our experimental observations with numerical simulations of Dysthe and of Euler equations. [ABSTRACT FROM AUTHOR]

Published

2022

2. Nonlinear random optical waves: Integrable turbulence, rogue waves and intermittency.

Author

Randoux, Stéphane, Walczak, Pierre, Onorato, Miguel, and Suret, Pierre

Subjects

*NONLINEAR waves, *OPTICAL waveguides, *TURBULENCE, *ROGUE waves, *INTERMITTENCY (Nuclear physics), *GAUSSIAN distribution, *SCHRODINGER equation

Abstract

We examine the general question of statistical changes experienced by ensembles of nonlinear random waves propagating in systems ruled by integrable equations. In our study that enters within the framework of integrable turbulence, we specifically focus on optical fiber systems accurately described by the integrable one-dimensional nonlinear Schrödinger equation. We consider random complex fields having a Gaussian statistics and an infinite extension at initial stage. We use numerical simulations with periodic boundary conditions and optical fiber experiments to investigate spectral and statistical changes experienced by nonlinear waves in focusing and in defocusing propagation regimes. As a result of nonlinear propagation, the power spectrum of the random wave broadens and takes exponential wings both in focusing and in defocusing regimes. Heavy-tailed deviations from Gaussian statistics are observed in focusing regime while low-tailed deviations from Gaussian statistics are observed in defocusing regime. After some transient evolution, the wave system is found to exhibit a statistically stationary state in which neither the probability density function of the wave field nor the spectrum changes with the evolution variable. Separating fluctuations of small scale from fluctuations of large scale both in focusing and defocusing regimes, we reveal the phenomenon of intermittency; i.e., small scales are characterized by large heavy-tailed deviations from Gaussian statistics, while the large ones are almost Gaussian. [ABSTRACT FROM AUTHOR]

Published

2016

3. Space–time observation of the dynamics of soliton collisions in a recirculating optical fiber loop.

Author

Copie, François, Suret, Pierre, and Randoux, Stéphane

Subjects

*SOLITON collisions, *INVERSE scattering transform, *NONLINEAR Schrodinger equation, *OPTICAL fibers, *NONLINEAR waves

Abstract

We present experiments performed in a recirculating fiber loop in which we realize the single-shot observation of the space and time interaction of two and three bright solitons. The space–time evolutions observed in experiments provide clear evidence of a nearly-integrable nonlinear wave dynamics that can be easily interpreted within the framework of the inverse scattering transform (IST) method. In particular collisions between solitons are found to be almost perfectly elastic in the sense that they occur without velocity change and with only a position (time) shift quantitatively well described by numerical simulations of the integrable nonlinear Schrödinger equation. Additionally our experiments provide the evidence that the position (time) shifts arising from the interaction among three solitons are determined by elementary pairwise interactions, as it is well known in the IST theory. [Display omitted] • We observe in single-shot the interaction of solitons in a recirculating fiber loop. • Experiments illustrate all the predicted features of soliton collision. • Several scenarios of three solitons interaction are investigated. [ABSTRACT FROM AUTHOR]

Published

2023

4. Early stage of integrable turbulence in the one-dimensional nonlinear Schrödinger equation: A semiclassical approach to statistics.

Author

Roberti, Giacomo, El, Gennady, Randoux, Stéphane, and Suret, Pierre

Subjects

*NONLINEAR Schrodinger equation, *PROBABILITY density function, *SCHRODINGER equation, *DISTRIBUTION (Probability theory), *RANDOM fields, *TURBULENCE

Abstract

We examine statistical properties of integrable turbulence in the defocusing and focusing regimes of one-dimensional small-dispersion nonlinear Schrödinger equation (1D-NLSE). Specifically, we study the 1D-NLSE evolution of partially coherent waves having Gaussian statistics at time t=0. Using short time asymptotic expansions and taking advantage of the scale separation in the semiclassical regime we obtain a simple explicit formula describing an early stage of the evolution of the fourth moment of the random wave field amplitude, a quantitative measure of the "tailedness" of the probability density function. Our results show excellent agreement with numerical simulations of the full 1D-NLSE random field dynamics and provide insight into the emergence of the well-known phenomenon of heavy (respectively, low) tails of the statistical distribution occurring in the focusing (respectively, defocusing) regime of 1D-NLSE. [ABSTRACT FROM AUTHOR]

Published

2019

5. Nonlinear Spectral Synthesis of Soliton Gas in Deep-Water Surface Gravity Waves.

Author

Suret, Pierre, Tikan, Alexey, Bonnefoy, Félicien, Copie, François, Ducrozet, Guillaume, Gelash, Andrey, Prabhudesai, Gaurav, Michel, Guillaume, Cazaubiel, Annette, Falcon, Eric, El, Gennady, and Randoux, Stéphane

Subjects

*GRAVITY waves, *NONLINEAR Schrodinger equation, *SYNTHESIS gas, *INVERSE scattering transform, *PROBABILITY density function, *SPECTRAL theory

Abstract

Soliton gases represent large random soliton ensembles in physical systems that exhibit integrable dynamics at the leading order. Despite significant theoretical developments and observational evidence of ubiquity of soliton gases in fluids and optical media, their controlled experimental realization has been missing. We report a controlled synthesis of a dense soliton gas in deep-water surface gravity waves using the tools of nonlinear spectral theory [inverse scattering transform (IST)] for the one-dimensional focusing nonlinear Schrödinger equation. The soliton gas is experimentally generated in a one-dimensional water tank where we demonstrate that we can control and measure the density of states, i.e., the probability density function parametrizing the soliton gas in the IST spectral phase space. Nonlinear spectral analysis of the generated hydrodynamic soliton gas reveals that the density of states slowly changes under the influence of perturbative higher-order effects that break the integrability of the wave dynamics. [ABSTRACT FROM AUTHOR]

Published

2020

6. Bound State Soliton Gas Dynamics Underlying the Spontaneous Modulational Instability.

Author

Gelash, Andrey, Agafontsev, Dmitry, Zakharov, Vladimir, El, Gennady, Randoux, Stéphane, and Suret, Pierre

Subjects

*MODULATIONAL instability, *GAS dynamics, *BOUND states, *INVERSE scattering transform, *NONLINEAR Schrodinger equation, *LONG-Term Evolution (Telecommunications)

Abstract

We investigate the fundamental phenomenon of the spontaneous, noise-induced modulational instability (MI) of a plane wave. The statistical properties of the noise-induced MI, observed previously in numerical simulations and in experiments, have not been explained theoretically. In this Letter, using the inverse scattering transform (IST) formalism, we propose a theoretical model of the asymptotic stage of the noise-induced MI based on N-soliton solutions of the focusing one-dimensional nonlinear Schrödinger equation. Specifically, we use ensembles of N-soliton bound states having a special semiclassical distribution of the IST eigenvalues, together with random phases for norming constants. To verify our model, we employ a recently developed numerical approach to construct an ensemble of N-soliton solutions with a large number of solitons, N~100. Our investigation reveals a remarkable agreement between spectral (Fourier) and statistical properties of the long-term evolution of the MI and those of the constructed multisoliton, random-phase bound states. Our results can be generalized to a broad class of strongly nonlinear integrable turbulence problems. [ABSTRACT FROM AUTHOR]

Published

2019