Fully nonlinear internal waves in a two-fluid system

WOOYOUNG CHOI; ROBERTO CAMASSA

doi:10.1017/S0022112099005820

Abstract

Model equations that govern the evolution of internal gravity waves at the interface of two immiscible inviscid fluids are derived. These models follow from the original Euler equations under the sole assumption that the waves are long compared to the undisturbed thickness of one of the fluid layers. No smallness assumption on the wave amplitude is made. Both shallow and deep water configurations are considered, depending on whether the waves are assumed to be long with respect to the total undisturbed thickness of the fluids or long with respect to just one of the two layers, respectively. The removal of the traditional weak nonlinearity assumption is aimed at improving the agreement with the dynamics of Euler equations for large-amplitude waves. This is obtained without compromising much of the simplicity of the previously known weakly nonlinear models. Compared to these, the fully nonlinear models' most prominent feature is the presence of additional nonlinear dispersive terms, which coexist with the typical linear dispersive terms of the weakly nonlinear models. The fully nonlinear models contain the Korteweg–de Vries (KdV) equation and the Intermediate Long Wave (ILW) equation, for shallow and deep water configurations respectively, as special cases in the limit of weak nonlinearity and unidirectional wave propagation. In particular, for a solitary wave of given amplitude, the new models show that the characteristic wavelength is larger and the wave speed is smaller than their counterparts for solitary wave solutions of the weakly nonlinear equations. These features are compared and found in overall good agreement with available experimental data for solitary waves of large amplitude in two-fluid systems.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Hu, Jianlan Feng, X. and Li, Zhi 2000. Exact traveling wave solutions of some nonlinear physical models. I. The fifth order KdV type equations. Communications in Nonlinear Science and Numerical Simulation, Vol. 5, Issue. 3, p. 118.

Kataoka, Takeshi Tsutahara, Michihisa and Akuzawa, Tomonori 2000. Two-Dimensional Evolution Equation of Finite-Amplitude Internal Gravity Waves in a Uniformly Stratified Fluid. Physical Review Letters, Vol. 84, Issue. 7, p. 1447.

Small, Justin 2001. A Nonlinear Model of the Shoaling and Refraction of Interfacial Solitary Waves in the Ocean. Part I: Development of the Model and Investigations of the Shoaling Effect. Journal of Physical Oceanography, Vol. 31, Issue. 11, p. 3163.

Clarke, S. R. and Johnson, E. R. 2001. The weakly nonlinear limit of forced Rossby waves in a stepped channel. Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, Vol. 457, Issue. 2014, p. 2361.

Small, Justin 2001. A Nonlinear Model of the Shoaling and Refraction of Interfacial Solitary Waves in the Ocean. Part II: Oblique Refraction across a Continental Slope and Propagation over a Seamount. Journal of Physical Oceanography, Vol. 31, Issue. 11, p. 3184.

Li, Yi A. 2001. Linear stability of solitary waves of the Green‐Naghdi equations. Communications on Pure and Applied Mathematics, Vol. 54, Issue. 5, p. 501.

Lynett, Patrick J. and Liu, Philip L.-F. 2002. A two-dimensional, depth-integrated model for internal wave propagation over variable bathymetry. Wave Motion, Vol. 36, Issue. 3, p. 221.

Mehta, A. P. Sutherland, B. R. and Kyba, P. J. 2002. Interfacial gravity currents. II. Wave excitation. Physics of Fluids, Vol. 14, Issue. 10, p. 3558.

Bakhanov, Victor V. and Ostrovsky, Lev A. 2002. Action of strong internal solitary waves on surface waves. Journal of Geophysical Research: Oceans, Vol. 107, Issue. C10,

Valentine, Daniel T. and Sipcic, Radica 2002. Nonlinear Internal Solitary Wave on a Pycnocline . Journal of Offshore Mechanics and Arctic Engineering, Vol. 124, Issue. 3, p. 120.

Jo, Tae‐Chang and Choi, Wooyoung 2002. Dynamics of Strongly Nonlinear Internal Solitary Waves in Shallow Water. Studies in Applied Mathematics, Vol. 109, Issue. 3, p. 205.

Antar, N. and Moodie, T. B. 2003. Weakly Nonhydrostatic Effects in Compositionally‐Driven Gravity Flows. Studies in Applied Mathematics, Vol. 111, Issue. 2, p. 239.

Dellar, Paul J. 2003. Dispersive shallow water magnetohydrodynamics. Physics of Plasmas, Vol. 10, Issue. 3, p. 581.

Small, Justin 2003. Refraction and Shoaling of Nonlinear Internal Waves at the Malin Shelf Break*. Journal of Physical Oceanography, Vol. 33, Issue. 12, p. 2657.

Ostrovsky, Lev A. and Grue, John 2003. Evolution equations for strongly nonlinear internal waves. Physics of Fluids, Vol. 15, Issue. 10, p. 2934.

Sherief, H H Faltas, M S and Saad, E I 2003. Forced gravity waves in two-layered fluids with the upper fluid having a free surface. Canadian Journal of Physics, Vol. 81, Issue. 4, p. 675.

Choi, Wooyoung 2003. Strongly nonlinear long gravity waves in uniform shear flows. Physical Review E, Vol. 68, Issue. 2,

SHINTANI, Tetsuya and UMEYAMA, Motohiko 2004. NUMERICAL SIMULATION AND VISUALIZATION EXPERIMENT OF INTERNAL WAVES ON AN UPPER SLOPE. Doboku Gakkai Ronbunshu, Vol. 2004, Issue. 768, p. 79.

Zhao, Zhongxiang Klemas, Victor Zheng, Quanan Li, Xiaofeng and Yan, Xiao-Hai 2004. Estimating parameters of a two-layer stratified ocean from polarity conversion of internal solitary waves observed in satellite SAR images. Remote Sensing of Environment, Vol. 92, Issue. 2, p. 276.

Ramp, S.R. Tang, T.Y. Duda, T.F. Lynch, J.F. Liu, A.K. Chiu, C.-S. Bahr, F.L. Kim, H.-R. and Yang, Y.-J. 2004. Internal Solitons in the Northeastern South China Sea Part I: Sources and Deep Water Propagation. IEEE Journal of Oceanic Engineering, Vol. 29, Issue. 4, p. 1157.

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Fully nonlinear internal waves in a two-fluid system

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