Modulation-resonance mechanism for surface waves in a two-layer fluid system

We propose a Boussinesq-type model to study the surface/interfacial wave manifestation of an underlying, slowly varying, long-wavelength baroclinic flow in a two-layer, density-stratified system. The results of our model show numerically that, under strong nonlinearity, surface waves, with their typ...

Full description

Saved in:
Bibliographic Details
Published in:Journal of fluid mechanics 2019-09, Vol.875, p.807-841
Main Authors: Jiang, Shixiao W., Kovačič, Gregor, Zhou, Douglas, Cai, David
Format: Article
Language:English
Subjects:
Amplitude
Amplitudes
Baroclinic flow
Boussinesq approximation
Boussinesq equations
Computer simulation
Fluid mechanics
Fluids
Group velocity
Interfacial waves
Internal waves
JFM Papers
Mathematical models
Modulation
Nonlinear systems
Nonlinearity
Resonance
Surface properties
Surface water waves
Surface waves
Theory
Velocity
Wavelength
Wavelengths
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We propose a Boussinesq-type model to study the surface/interfacial wave manifestation of an underlying, slowly varying, long-wavelength baroclinic flow in a two-layer, density-stratified system. The results of our model show numerically that, under strong nonlinearity, surface waves, with their typical wavenumber being the resonant $k_{res}$ , can be generated locally at the leading edge of the underlying, slowly varying, long-wavelength baroclinic flow. Here, the resonant $k_{res}$ satisfies the class 3 triad resonance condition among two short-mode waves and one long-mode wave in which all waves propagate in the same direction. Moreover, when the slope of the baroclinic flow is sufficiently small, only one spatially localized large-amplitude surface wave packet can be generated at the leading edge. This localized surface wave packet becomes high in amplitude and large in group velocity after the interaction with its surrounding waves. These results are qualitatively consistent with various experimental observations including resonant surface waves at the leading edge of an internal wave. Subsequently, we propose a mechanism, referred to as the modulation-resonance mechanism, underlying these surface phenomena, based on our numerical simulations. The proposed modulation-resonance mechanism combines the linear modulation, ray-based, theory for the spatiotemporal asymmetric behaviour of surface waves and the nonlinear class 3 triad resonance theory for the energy focusing of surface waves around the resonant wavenumber $k_{res}$ in Fourier space.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2019.501