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Autores principales: Colleaux, Clement, Skipp, Jonathan, Nazarenko, Sergey, Laurie, Jason
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.12507
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author Colleaux, Clement
Skipp, Jonathan
Nazarenko, Sergey
Laurie, Jason
author_facet Colleaux, Clement
Skipp, Jonathan
Nazarenko, Sergey
Laurie, Jason
contents We study numerically the nonintegrable dynamics of coherent, solitonic, nonlinear waves, in a spatially nonlocal nonlinear Schrodinger equation relevant to realistic modelling of optical systems: the Schrodinger-Helmholtz equation. We observe a single oscillating, coherent solitary wave emerging from a variety of initial conditions. Using the direct scattering transform of the (integrable) cubic nonlinear Schrodinger equation, we find that this structure is a bound state, comprising of a primary and secondary soliton whose amplitudes oscillate out of phase. We interpret this as the solitons periodically exchanging mass. We observe this bound state self-organising from a state of incoherent turbulence, and from solitonic structures launched into the system. When a single (primary) solitonic structure is launched, a resonance process between it and waves in the system generates the secondary soliton, resulting in the bound state. Further, when two solitons are initially launched, we show that they can merge if their phases are synchronised when they collide. When the system is launched from a turbulent state comprised of many initial solitons, we propose that the bound state formation is preceded a sequence of binary collisions, in which the mass is transferred on average from the weak soliton to the strong one, with occasional soliton mergers. Both processes lead to increasingly stronger and fewer dominant solitons. The final state -- a solitary double-solitonic bound state surrounded by weakly nonlinear waves -- is robust and ubiquitous. We propose that for nonlocal media, it is a more typical statistical attractor than a single-soliton attractor suggested in previous literature.
format Preprint
id arxiv_https___arxiv_org_abs_2410_12507
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A bound state attractor in optical turbulence
Colleaux, Clement
Skipp, Jonathan
Nazarenko, Sergey
Laurie, Jason
Pattern Formation and Solitons
Computational Physics
Optics
We study numerically the nonintegrable dynamics of coherent, solitonic, nonlinear waves, in a spatially nonlocal nonlinear Schrodinger equation relevant to realistic modelling of optical systems: the Schrodinger-Helmholtz equation. We observe a single oscillating, coherent solitary wave emerging from a variety of initial conditions. Using the direct scattering transform of the (integrable) cubic nonlinear Schrodinger equation, we find that this structure is a bound state, comprising of a primary and secondary soliton whose amplitudes oscillate out of phase. We interpret this as the solitons periodically exchanging mass. We observe this bound state self-organising from a state of incoherent turbulence, and from solitonic structures launched into the system. When a single (primary) solitonic structure is launched, a resonance process between it and waves in the system generates the secondary soliton, resulting in the bound state. Further, when two solitons are initially launched, we show that they can merge if their phases are synchronised when they collide. When the system is launched from a turbulent state comprised of many initial solitons, we propose that the bound state formation is preceded a sequence of binary collisions, in which the mass is transferred on average from the weak soliton to the strong one, with occasional soliton mergers. Both processes lead to increasingly stronger and fewer dominant solitons. The final state -- a solitary double-solitonic bound state surrounded by weakly nonlinear waves -- is robust and ubiquitous. We propose that for nonlocal media, it is a more typical statistical attractor than a single-soliton attractor suggested in previous literature.
title A bound state attractor in optical turbulence
topic Pattern Formation and Solitons
Computational Physics
Optics
url https://arxiv.org/abs/2410.12507