Two-Dimensional Evolution Equation of Finite-Amplitude Internal Gravity Waves in a Uniformly Stratified Fluid

A Helmholtz velocity profile with velocity discontinuity 2U is embedded in an infinite continuously stratified Boussinesq fluid with constant Brunt—Väisälä frequency N. Linear theory shows that this system can support resonant over-reflexion, i.e. the existence of neutral modes consisting of outgoing internal gravity waves, whenever the horizontal wavenumber is less than N/2½U. This paper examines the weakly nonlinear theory of these modes. An equation governing the evolution of the amplitude of the interface displacement is derived. The time scale for this evolution is α−2, where α is a measure of the magnitude of the interface displacement, which is excited by an incident wave of magnitude O(α3). It is shown that the mode which is symmetrical with respect to the interface (and has a horizontal phase speed equal to the mean of the basic velocity discontinuity) remains neutral, with a finite amplitude wave on the interface. However, the other modes, which are not symmetrical with respect to the interface, become unstable owing to the self-interaction of the primary mode with its second harmonic. The interface displacement develops a singularity in a finite time.

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Scattering of internal tides by irregular bathymetry of large extent

Journal of Fluid Mechanics ◽

10.1017/jfm.2014.159 ◽

2014 ◽

Vol 747 ◽

pp. 481-505 ◽

Cited By ~ 6

Author(s):

Yile Li ◽

Chiang C. Mei

Keyword(s):

Gravity Waves ◽

Method Of Characteristics ◽

Multiple Scales ◽

Method Of Multiple Scales ◽

Internal Gravity Waves ◽

Internal Tides ◽

Two Dimensional ◽

One Dimensional ◽

Stratified Ocean ◽

Stationary Random Function

AbstractWe present an analytical theory of scattering of tide-generated internal gravity waves in a continuously stratified ocean with a randomly rough seabed. Based on a linearized approximation, the idealized case of constant mean sea depth and Brunt–Väisälä frequency is considered. The depth fluctuation is assumed to be a stationary random function of space, characterized by small amplitude and a correlation length comparable to the typical wavelength. For both one- and two-dimensional topographies the effects of scattering on the wave phase over long distances are derived explicitly by the method of multiple scales. For one-dimensional topography, numerical results are compared with Bühler & Holmes-Cerfon (J. Fluid Mech., vol. 678, 2011, pp. 271–293), computed by the method of characteristics. For two-dimensional topography, new results are presented for both statistically isotropic and anisotropic cases.

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On the appearance of internal wave attractors due to an initial or parametrically excited disturbance

Journal of Fluid Mechanics ◽

10.1017/jfm.2012.479 ◽

2013 ◽

Vol 714 ◽

pp. 283-311 ◽

Cited By ~ 9

Author(s):

Janis Bajars ◽

Jason Frank ◽

Leo R. M. Maas

Keyword(s):

Gravity Waves ◽

Normal Modes ◽

Internal Gravity Waves ◽

Harmonic Oscillators ◽

Two Dimensional ◽

Boussinesq Model ◽

Resonant Modes ◽

The Waves ◽

Shaped Domain ◽

Parametric Forcing

AbstractIn this paper we solve two initial value problems for two-dimensional internal gravity waves. The waves are contained in a uniformly stratified, square-shaped domain whose sidewalls are tilted with respect to the direction of gravity. We consider several disturbances of the initial stream function field and solve both for its free evolution and for its evolution under parametric excitation. We do this by developing a structure-preserving numerical method for internal gravity waves in a two-dimensional stratified fluid domain. We recall the linearized, inviscid Euler–Boussinesq model, identify its Hamiltonian structure, and derive a staggered finite difference scheme that preserves this structure. For the discretized model, the initial condition can be projected onto normal modes whose dynamics is described by independent harmonic oscillators. This fact is used to explain the persistence of various classes of wave attractors in a freely evolving (i.e. unforced) flow. Under parametric forcing, the discrete dynamics can likewise be decoupled into Mathieu equations. The most unstable resonant modes dominate the solution, forming wave attractors.

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The theory of symmetrical gravity waves of finite amplitude. I

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1951.0175 ◽

1951 ◽

Vol 208 (1095) ◽

pp. 475-486 ◽

Cited By ~ 18

Keyword(s):

Boundary Condition ◽

Gravity Waves ◽

Finite Amplitude ◽

Breaking Wave ◽

Two Dimensional ◽

Linear Boundary ◽

Dimensional Problem ◽

Infinite Depth ◽

Linear Boundary Condition ◽

Small Parameters

The two-dimensional problem of symmetric finite amplitude gravity waves in an incompressible fluid of infinite depth is treated by a method which first involves satisfying a non-linear boundary condition exactly. The higher approximations are obtained by the method of small parameters. The breaking-wave conditions are discussed and expressions are given for the free-surface equation, the kinetic and the potential energies of the fluid.

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Momentum Flux Spectrum of Convectively Forced Internal Gravity Waves and Its Application to Gravity Wave Drag Parameterization. Part I: Theory

Journal of the Atmospheric Sciences ◽

10.1175/jas-3363.1 ◽

2005 ◽

Vol 62 (1) ◽

pp. 107-124 ◽

Cited By ~ 53

Author(s):

In-Sun Song ◽

Hye-Yeong Chun

Keyword(s):

Gravity Waves ◽

Momentum Flux ◽

Three Dimensional ◽

Internal Gravity Waves ◽

Buoyancy Frequency ◽

Spectral Structure ◽

Two Dimensional ◽

Resonance Factor ◽

Flux Spectrum ◽

Wave Momentum

Abstract The phase-speed spectrum of momentum flux by convectively forced internal gravity waves is analytically formulated in two- and three-dimensional frameworks. For this, a three-layer atmosphere that has a constant vertical wind shear in the lowest layer, a uniform wind above, and piecewise constant buoyancy frequency in a forcing region and above is considered. The wave momentum flux at cloud top is determined by the spectral combination of a wave-filtering and resonance factor and diabatic forcing. The wave-filtering and resonance factor that is determined by the basic-state wind and stability and the vertical configuration of forcing restricts the effectiveness of the forcing, and thus only a part of the forcing spectrum can be used for generating gravity waves that propagate above cumulus clouds. The spectral distribution of the wave momentum flux is largely determined by the wave-filtering and resonance factor, but the magnitude of the momentum flux varies significantly according to spatial and time scales and moving speed of the forcing. The wave momentum flux formulation in the two-dimensional framework is extended to the three-dimensional framework. The three-dimensional momentum flux formulation is similar to the two-dimensional one except that the wave propagation in various horizontal directions and the three-dimensionality of forcing are allowed. The wave momentum flux spectrum formulated in this study is validated using mesoscale numerical model results and can reproduce the overall spectral structure and magnitude of the wave momentum flux spectra induced by numerically simulated mesoscale convective systems reasonably well.

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On the shape and breaking of finite amplitude internal gravity waves in a shear flow

Journal of Fluid Mechanics ◽

10.1017/s0022112078000518 ◽

1978 ◽

Vol 85 (1) ◽

pp. 7-31 ◽

Cited By ~ 58

Author(s):

S. A. Thorpe

Keyword(s):

Shear Flow ◽

Internal Waves ◽

Gravity Waves ◽

Second Harmonic ◽

Mixing Layer ◽

Phase Speed ◽

Internal Gravity Waves ◽

Finite Amplitude ◽

Depth Interval ◽

Plane Shear

This paper is concerned with two important aspects of nonlinear internal gravity waves in a stably stratified inviscid plane shear flow, their shape and their breaking, particularly in conditions which are frequently encountered in geophysical applications when the vertical gradients of the horizontal current and the density are concentrated in a fairly narrow depth interval (e.g. the thermocline in the ocean). The present theoretical and experimental study of the wave shape extends earlier work on waves in the absence of shear and shows that the shape may be significantly altered by shear, the second-harmonic terms which describe the wave profile changing sign when the shear is increased sufficiently in an appropriate sense.In the second part of the paper we show that the slope of internal waves at which breaking occurs (the particle speeds exceeding the phase speed of the waves) may be considerably reduced by the presence of shear. Internal waves on a thermocline which encounter an increasing shear, perhaps because of wind action accelerating the upper mixing layer of the ocean, may be prone to such breaking.This work may alternatively be regarded as a study of the stability of a parallel stratified shear flow in the presence of a particular finite disturbance which corresponds to internal gravity waves propagating horizontally in the plane of the flow.

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Transport by breaking internal gravity waves on slopes

Journal of Fluid Mechanics ◽

10.1017/jfm.2015.723 ◽

2016 ◽

Vol 789 ◽

pp. 93-126 ◽

Cited By ~ 19

Author(s):

Robert S. Arthur ◽

Oliver B. Fringer

Keyword(s):

Gravity Waves ◽

Wave Breaking ◽

Internal Gravity Waves ◽

Length Scale ◽

Two Dimensional ◽

Turbulent Diffusivity ◽

Nepheloid Layer ◽

Molecular Diffusivity ◽

Tracking Model ◽

Offshore Transport

We use the results of a direct numerical simulation (DNS) with a particle-tracking model to investigate three-dimensional transport by breaking internal gravity waves on slopes. Onshore transport occurs within an upslope surge of dense fluid after breaking. Offshore transport occurs due to an intrusion of mixed fluid that propagates offshore and resembles an intermediate nepheloid layer (INL). Entrainment of particles into the INL is related to irreversible mixing of the density field during wave breaking. Maximum onshore and offshore transport are calculated as a function of initial particle position, and can be of the order of the initial wave length scale for particles initialized within the breaking region. An effective cross-shore dispersion coefficient is also calculated, and is roughly three orders of magnitude larger than the molecular diffusivity within the breaking region. Particles are transported laterally due to turbulence that develops during wave breaking, and this lateral spreading is quantified with a lateral turbulent diffusivity. Lateral turbulent diffusivity values calculated using particles are elevated by more than one order of magnitude above the molecular diffusivity, and are shown to agree well with turbulent diffusivities estimated using a generic length scale turbulence closure model. Based on a favourable comparison of DNS results with those of a similar two-dimensional case, we use two-dimensional simulations to extend our cross-shore transport results to additional wave amplitude and bathymetric slope conditions.

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The propagation of viscous, linear internal gravity waves through critical levels in a sheared, stably stratified fluid

Il Nuovo Cimento B ◽

10.1007/bf02749418 ◽

1976 ◽

Vol 36 (1) ◽

pp. 21-33

Author(s):

R. Lupini

Keyword(s):

Gravity Waves ◽

Internal Gravity Waves ◽

Stratified Fluid ◽

Critical Levels

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Note on the velocity and related fields of steady irrotational two-dimensional surface gravity waves

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2011.0470 ◽

2012 ◽

Vol 370 (1964) ◽

pp. 1572-1586 ◽

Cited By ~ 30

Author(s):

Didier Clamond

Keyword(s):

Gravity Waves ◽

Finite Amplitude ◽

Numerical Results ◽

Surface Gravity ◽

Two Dimensional ◽

Surface Gravity Waves ◽

Stokes Waves ◽

Irrotational Motion ◽

Dimensional Surface

The velocity and other fields of steady two-dimensional surface gravity waves in irrotational motion are investigated numerically. Only symmetric waves with one crest per wavelength are considered, i.e. Stokes waves of finite amplitude, but not the highest waves, nor subharmonic and superharmonic bifurcations of Stokes waves. The numerical results are analysed, and several conjectures are made about the velocity and acceleration fields.

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