Branched flow and caustics in nonlinear waves

Green, Gerrit; Fleischmann, Ragnar

doi:10.1088/1367-2630/ab319b

Cited by 12 publications

(5 citation statements)

References 34 publications

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“…The branching, while somewhat smoothed off by a 10% or 20% dispersion in initial wave direction, actually survives in quite high contrast and surprisingly develops more contrast and even finer structure downstream (figure 6). The excess freak wave probability was accounted for without involving nonlinear effects (not denying their crucial importance in the "end game" of the formation of a very large wave 22 ) by nonuniform Gaussian sampling over the energy density of branches of the branches surviving the fuzzy manifold. It is thus possible that the ignition step of freak waves is still in the linear regime.…”

Section: Ocean Freak Wavesmentioning

confidence: 99%

Branched Flow

Heller,

Fleischmann,

Kramer

2019

Preprint

Self Cite

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Section: Ocean Freak Wavesmentioning

confidence: 99%

Branched Flow

Heller,

Fleischmann,

Kramer

2019

Preprint

Self Cite

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“…The assumption of slow spatial variation of properties enables the simplification of the wave elastodynamics to a set of ray equations using the eikonal/ WKB approximations [26,27]. They are further simplified using the paraxial approximation [28], permitted by the weak scattering nature of the problem, which asserts a predominantly axial direction of the wave vector. These ray equations are then used to analytically derive the scaling law (Eq 1) relating the position of focusing and the severity of the non-homogeneity.…”

Section: Resultsmentioning

confidence: 99%

Branched flows of flexural elastic waves in non-uniform cylindrical shells

2023

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Propagation of elastic waves along the axis of cylindrical shells is of great current interest due to their ubiquitous presence and technological importance. Geometric imperfections and spatial variations of properties are inevitable in such structures. Here we report the existence of branched flows of flexural waves in such waveguides. The location of high amplitude motion, away from the launch location, scales as a power law with respect to the variance, and linearly with respect to the correlation length of the spatial variation in the bending stiffness. These scaling laws are then theoretically derived from the ray equations. Numerical integration of the ray equations also exhibit this behaviour—consistent with finite element numerical simulations as well as the theoretically derived scaling. There appears to be a universality for the exponents in the scaling with respect to similar observations in the past for waves in other physical contexts, as well as dispersive flexural waves in elastic plates.

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“…The assumption of slow spatial variation of properties enables the simplification of the wave elastodynamics to a set of ray equations using the eikonal/WKB approximations 22,23 . They are further simplified using the paraxial approximation 24 , permitted by the weak scattering nature of the problem, which asserts a predominantly axial direction of the wave vector. These ray equations are then used to analytically derive the scaling law (Equation 1) relating the position of focusing and the severity of the non-homogeneity.…”

Section: Resultsmentioning

confidence: 99%

Branched flows of flexural waves in non-uniform elastic plates

2022

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Flexural elastic waves and sound in solids are of great interest in wide-ranging contexts such as ultrasound in plates, geophysics, ocean engineering, aerospace and automotive structures, and musical acoustics. Despite bending waves being the most important elastic waves for such surface structures, their propagation in the presence of the inevitable non-uniformity is poorly understood. Here we show the branching and focusing behaviour of highly dispersive flexural waves travelling in elastic plates of non-uniform thickness. The thickness profile has isotropically correlated spatial randomness. The correlation length is much larger than the wavelength. The location of wave focusing shows a scaling relationship with randomness, which is consistent with those previously reported in other random media. We show this analytically and numerically. This suggests a universality in the scaling between the location of wave focusing with randomness and the correlation length, regardless of the physics of the waves in question.

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Branched flow and caustics in nonlinear waves

Cited by 12 publications

References 34 publications

Branched Flow

Branched Flow

Branched flows of flexural elastic waves in non-uniform cylindrical shells

Branched flows of flexural waves in non-uniform elastic plates

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