Dynamics of Three-Dimensional Gravity-Capillary Solitary Waves in Deep Water

Akers, Benjamin F.; Milewski, Paul A.

doi:10.1137/090758386

Cited by 39 publications

(53 citation statements)

References 30 publications

(32 reference statements)

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“…The details of these computations can be found in Akers & Milewski (2010). An interesting particularity is that the physical energy for two dimensional wavepacket solitary waves is predicted to tend to a finite value of 12.04 as the amplitude approaches zero, which we shall verify in the cDtNE model.…”

Section: The Nonlinear Schrödinger Equationmentioning

confidence: 58%

“…For plane solitary waves, the linear analysis based on NLS (see Akers & Milewski (2010)) shows that the transverse perturbation e ily is unstable, when the wave number l in the y direction satisfies…”

Section: Stability Focussing and Wave Collapsementioning

confidence: 99%

“…Line solitary waves are unstable to transverse perturbations of sufficiently long wavelength. Fully 2D dynamics have been considered by Akers & Milewski (2010) in a one-way simplified model and in a quadratic isotropic model in Akers & Milewski (2009). The main goal of this paper is to study 2D dynamics within a close approximation of the Euler equations.…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of gravity–capillary solitary waves in deep water

Wang

Milewski

2012

J. Fluid Mech.

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The dynamics of solitary gravity-capillary water waves propagating on the surface of a three-dimensional fluid domain is studied numerically. In order to accurately compute complex time dependent solutions, we simplify the full potential flow problem by taking a cubic truncation of the scaled Dirichlet-to-Neumann operator for the normal velocity on the free surface. This approximation agrees remarkably well with the full equations for the bifurcation curves, wave profiles and the dynamics of solitary waves for a twodimensional fluid domain. Fully localised solitary waves are then computed in the threedimensional problem and the stability and interaction of both line and localized solitary waves are investigated via numerical time integration of the equations. The solitary wave branches are indexed by their finite energy at small amplitude, and the dynamics of the solitary waves is complex involving nonlinear focussing of wave packets, quasi-elastic collisions, and the generation of propagating, spatially localised, time-periodic structures (breathers).

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Section: The Nonlinear Schrödinger Equationmentioning

confidence: 58%

Section: Stability Focussing and Wave Collapsementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Dynamics of gravity–capillary solitary waves in deep water

Wang

Milewski

2012

J. Fluid Mech.

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“…Beginning with the Crapper wave, we observe that waves become more localized with increased Bond number. As σ increases, profiles become more solitary than periodic, gaining oscillatory tails similar to those computed in [47,50]. These changes occur at all amplitudes, see figure 1 for the case of y ∞ = 0.2, however, the size of oscillations in the tail decreases with amplitude.…”

Section: Numerical Resultsmentioning

confidence: 57%

“…When the system is discretized with N spatial points, we must then solve for N Fourier modes and the wave speed c. The projection of the partial differential equation into Fourier space gives N equations, to which we append an equation fixing the amplitude to close the system. The resulting nonlinear system of algebraic equations is then solved via Broyden's method, and continuation in amplitude or gravity, similar to [47,48].…”

Section: Numerical Resultsmentioning

confidence: 99%

Gravity perturbed Crapper waves

2014

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Crapper waves are a family of exact periodic travelling wave solutions of the free-surface irrotational incompressible Euler equations; these are pure capillary waves, meaning that surface tension is accounted for, but gravity is neglected. For certain parameter values, Crapper waves are known to have multi-valued height. Using the implicit function theorem, we prove that any of the Crapper waves can be perturbed by the effect of gravity, yielding the existence of gravity-capillary waves nearby to the Crapper waves. This result implies the existence of travelling gravity-capillary waves with multi-valued height. The solutions we prove to exist include waves with both positive and negative values of the gravity coefficient. We also compute these gravity perturbed Crapper waves by means of a quasi-Newton iterative scheme (again, using both positive and negative values of the gravity coefficient). A phase diagram is generated, which depicts the existence of singlevalued and multi-valued travelling waves in the gravity-amplitude plane. A new largest water wave is computed, which is composed of a string of bubbles at the interface.

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On the Motion of Gravity–Capillary Waves with Odd Viscosity

Granero-Belinchón

Ortega

2022

J Nonlinear Sci

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We develop three asymptotic models of surface waves in a non-Newtonian fluid with odd viscosity. This viscosity is also known as Hall viscosity and appears in a number of applications such as quantum Hall fluids or chiral active fluids. Besides the odd viscosity effects, these models capture both gravity and capillary forces up to quadratic interactions and take the form of nonlinear and nonlocal wave equations. Two of these models describe bidirectional waves, while the third PDE studies the case of unidirectional propagation. We also prove the well-posedness of these asymptotic models in spaces of analytic functions and in Sobolev spaces. Finally, we present a number of numerical simulations for the unidirectional model.

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Dynamics of Three-Dimensional Gravity-Capillary Solitary Waves in Deep Water

Cited by 39 publications

References 30 publications

Dynamics of gravity–capillary solitary waves in deep water

Dynamics of gravity–capillary solitary waves in deep water

Gravity perturbed Crapper waves

On the Motion of Gravity–Capillary Waves with Odd Viscosity

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