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On the highest non-breaking wave in a group: fully nonlinear water wave breathers versus weakly nonlinear theory

Published online by Cambridge University Press:  23 October 2013

Alexey V. Slunyaev*
Affiliation:
Department of Mathematics, EPSAM, Keele University, Keele ST5 5BG, UK Department of Nonlinear Geophysical Processes, Institute of Applied Physics, 46 Ulyanova Street, N. Novgorod 603950, Russia Nizhny Novgorod State Technical University, 24 Minina Street, N. Novgorod 603950, Russia
Victor I. Shrira
Affiliation:
Department of Mathematics, EPSAM, Keele University, Keele ST5 5BG, UK
*
Email address for correspondence: [email protected]

Abstract

In nature, water waves usually propagate in groups and the open question about the characteristics of the highest possible wave in a group is of significant theoretical and practical interest. We examine the problem of the highest non-breaking wave in a wave group by direct numerical simulations of the exact Euler equations. The main aim of the study is twofold: (i) to describe the highest wave in a group in fully nonlinear setting and find its dependence on parameters; (ii) to examine correspondence between the exact breather solutions of weakly nonlinear analytic theory based on the integrable nonlinear Schrödinger (NLS) equation and their strongly nonlinear analogues. In contrast to weakly nonlinear models the very notion of the highest wave is ill-defined: the maximal crest elevation, the maximal trough-to-crest height and the deepest trough all occur at close but different moments; correspondingly, we have to speak about distinctively different extreme waves. In the simulations small initial perturbation of a uniform wave train were prescribed in a way ensuring that the initial perturbation excites a single breather-type modulation. The ensuing growth results in higher wave magnitudes and takes longer time to develop compared with the NLS theory. The maxima of crest elevation noticeably exceed their weakly nonlinear analogues. The wave with the highest crest differs significantly from the unmodulated wave: the local wavelength contracts considerably, the crest becomes noticeably higher; the vicinity of the crest of such an extreme wave is close to that of the limiting Stokes periodic wave. Thus, the shape of the maximal crest wave is almost universal, i.e. it practically does not depend on the way the wave group evolved, or even whether there was initially more than one group. The evolution of a single NLS breather has been shown to have a qualitatively similar but quantitatively quite different analogue in the fully nonlinear setting. The one-to-one mapping of the NLS breather solutions onto fully nonlinear ones has been constructed. The fully nonlinear breathers are found to be robust, which provides grounds for applying the results for developing short-term deterministic forecasting of rogue waves.

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Papers
Copyright
©2013 Cambridge University Press 

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References

Ablowitz, M. J., Hammack, J., Henderson, D. & Schober, C. M. 2001 Long-time dynamics of the modulational instability of deep water waves. Physica D 152–153, 416433.Google Scholar
Ablowitz, M. J. & Herbst, B. M. 1990 On homoclinic structure and numerically induced chaos for the nonlinear Schrödinger equation. SIAM J. Appl. Maths 50, 339351.Google Scholar
Akhmediev, N. N. & Ankiewicz, A. 1997 Solitons - Nonlinear Pulses and Beams. Chapman & Hall.Google Scholar
Akhmediev, N., Ankiewicz, A. & Soto-Crespo, J. M. 2009 Rogue waves and rational solutions of the nonlinear Schrödinger equation. Phys. Rev. E 80, 026601.Google Scholar
Akhmediev, N. N., Eleonskii, V. M. & Kulagin, N. E. 1987 Exact first-order solutions of the nonlinear Schrödinger equation. Theor. Math. Phys. USSR 72, 809818.Google Scholar
Annenkov, S. Y. & Shrira, V. I. 2013 Large-time evolution of statistical moments of wind wave fields. J. Fluid Mech. 726, 517546.CrossRefGoogle Scholar
Babanin, A. 2011 Breaking and Dissipation of Ocean Surface Waves. Cambridge University Press.Google Scholar
Benjamin, T. B. & Feir, J. E. 1967 The disintegration of wavetrains in deep water. Part 1. J. Fluid Mech. 27, 417430.Google Scholar
Biausser, B., Fraunie, P., Grilli, S. & Marcer, R. 2004 Numerical analysis of the internal kinematics and dynamics of 3-D breaking waves on slopes. Intl J. Offshore Polar Engng 14, 247256.Google Scholar
Boccotti, P. 1997 A general theory of three-dimensional wave groups. Part I: the formal derivation. Ocean Engng 24, 265280.CrossRefGoogle Scholar
Chabchoub, A., Hoffmann, N. P. & Akhmediev, N 2011 Rogue wave observation in a water wave tank. Phys. Rev. Lett. 106, 204502.CrossRefGoogle Scholar
Chabchoub, A., Hoffmann, N., Onorato, M. & Akhmediev, N. 2012a Super rogue waves: observation of a higher-order breather in water waves. Phys. Rev. X 2, 011015.Google Scholar
Chabchoub, A., Hoffmann, N., Onorato, M., Slunyaev, A., Sergeeva, A., Pelinovsky, E. & Akhmediev, N. 2012b Observation of a hierarchy of up to fifth-order rogue waves in a water tank. Phys. Rev. E 86, 056601.Google Scholar
Clamond, D., Francius, M., Grue, J. & Kharif, C. 2006 Long time interaction of envelope solitons and freak wave formations. Eur. J. Mech. (B/Fluids) 25, 536553.Google Scholar
Clauss, G. F., Klein, M., Dudek, M. & Onorato, M. 2012 Application of breather solutions for the investigation of wave/structure interaction in high steep waves. Proceedings of 31th International Conference on Ocean, Offshore and Arctic Engineering, OMAE 83244-1–13.Google Scholar
Craik, A. D. D. 1985 Wave Interactions and Fluid Flows. Cambridge Monographs on Mechanics. Cambridge University Press.Google Scholar
Drazin, P. G. & Johnson, R. S. 1996 Solitons: an Introduction. Cambridge University Press.Google Scholar
Dubard, P., Gaillard, P., Klein, C. & Matveev, V. B. 2010 On multi-rogue wave solutions of the NLS equation and positon solutions of the KdV equation. Eur. Phys. J. Special Topics 185, 247258.Google Scholar
Dyachenko, A. I. & Zakharov, V. E. 2008 On the formation of freak waves on the surface of deep water. J. Expl Theor. Phys. Lett. 88, 307311.Google Scholar
Dysthe, K. B. 1979 Note on a modification to the nonlinear Schrödinger equation for application to deep water waves. Proc. R. Soc. Lond. A 369, 105114.Google Scholar
Dysthe, K., Krogstad, H. E. & Müller, P. 2008 Oceanic rogue waves. Annu. Rev. Fluid Mech. 40, 287310.CrossRefGoogle Scholar
Dysthe, K. B. & Trulsen, K. 1999 Note on breather type solutions of the NLS as models for freak-waves. Phys. Scr. T 82, 4852.Google Scholar
Fenton, J. D. 1985 A fifth-order Stokes theory for steady waves. J. Waterways Port Coast. Ocean Engng 111, 216234.Google Scholar
Gaillard, P. 2012 Wronskian representation of solutions of the NLS equation and higher Peregrine breathers. J. Math. Sci.: Adv. Appl. 13, 71153.Google Scholar
Henderson, K. L., Peregrine, D. H. & Dold, J. W. 1999 Unsteady water wave modulations: Fully nonlinear solutions and comparison with the nonlinear Schrödinger equation. Wave Motion 29, 341361.CrossRefGoogle Scholar
Iafrati, A., Babanin, A. & Onorato, M. Modulational instability, wave breaking and formation of large-scale dipoles in the atmosphere. Preprint (2012) arXiv: 1208.5392.Google Scholar
Islas, A. L. & Schober, C. M. 2005 Predicting rogue waves in random oceanic sea states. Phys. Fluids 17, 031701.CrossRefGoogle Scholar
Janssen, P. 2004 The Interaction of Surface Waves and Wind. Cambridge University Press.CrossRefGoogle Scholar
Karjanto, N. & van Groesen, E. 2010 Qualitative comparisons of experimental results on deterministic freak wave generation based on modulational instability. J. Hydro-environ. Res. 3, 186192.Google Scholar
Kharif, C., Pelinovsky, E. & Slunyaev, A. 2009 Rogue Waves in the Ocean. Springer.Google Scholar
Krasitskii, V. P. 1994 On reduced equations in the Hamiltonian theory of weakly nonlinear surface waves. J. Fluid Mech. 272, 120.CrossRefGoogle Scholar
Kuznetsov, E. A. 1977 Solitons in a parametrically unstable plasma. Sov. Phys. Dokl. 22, 507508.Google Scholar
Lautrup, B. 2011 Stokes waves. In Physics of Continuous Matter, Second Edition: Exotic and Everyday Phenomena in the Macroscopic World. CRC Press.Google Scholar
Lighthill, M. J. 1965 Contribution to the theory of waves in nonlinear dispersive systems. J. Inst. Maths Applics. 1, 269306.Google Scholar
Lindgren, G. 1970 Some properties of a normal process near a local maximum. Ann. Math. Statist. 4, 18701883.CrossRefGoogle Scholar
Lo, E. & Mei, C. C. 1985 A numerical study of water-wave modulation based on a higher-order nonlinear Schrödinger equation. J. Fluid Mech. 150, 395416.Google Scholar
Longuet-Higgins, M. S. 1975 Integral properties of periodic gravity waves of finite amplitude. Proc. R. Soc. Lond. A 342, 157174.Google Scholar
Longuet-Higgins, M. S. 1978 The instabilities of gravity waves of finite amplitude in deep water. II. Subharmonics. Proc. R. Soc. Lond. A 360, 489505.Google Scholar
Longuet-Higgins, M. S. 1984 On the stability of steep gravity waves. Proc. R. Soc. Lond. A 396, 269280.Google Scholar
Longuet-Higgins, M. S., Cleaver, R. P. & Fox, M. J. H. 1994 Crest instabilities of gravity waves. Part 2. Matching and asymptotic analysis. J. Fluid Mech. 259, 333344.CrossRefGoogle Scholar
Longuet-Higgins, M. S. & Cokelet, E. D. 1978 The deformation of steep surface waves on water. II. Growth of normal-mode instabilities. Proc. R. Soc. Lond. A 364, 128.Google Scholar
McLean, J. W. 1982 Instabilities of finite-amplitude water waves. J. Fluid Mech. 114, 315330.Google Scholar
Michell, J. H. 1893 The highest waves in water. Phil. Mag. Series 5 36, 430437.CrossRefGoogle Scholar
Newell, A. C. 1985 Solitons in Mathematics and Physics. Society for Industrial and Applied Mathematics.Google Scholar
Nieto Borge, J. C., Reichert, K. & Hessner, K. 2013 Detection of spatio-temporal wave grouping properties by using temporal sequences of X-band radar images of the sea surface pH. Ocean Model. 61, 2137.Google Scholar
Olagnon, M. & Athanassoulis, G. A. (Eds) 2001 Rogue Waves 2000. Ifremer.Google Scholar
Olagnon, M. & Prevosto, M. (Eds) 2005 Rogue Waves 2004. Ifremer.Google Scholar
Olagnon, M. & Prevosto, M. (Eds) 2009 Rogue Waves 2008. Ifremer.Google Scholar
Onorato, M., Waseda, T., Toffoli, A., Cavaleri, L., Gramstad, O., Janssen, P. A., Kinoshita, T., Monbaliu, J., Mori, N., Osborne, A. R., Serio, M., Stansberg, C. T., Tamura, H. & Trulsen, K. 2009 Statistical properties of directional ocean waves: the role of the modulational instability in the formation of extreme events. Phys. Rev. Lett. 102, 114502.Google Scholar
Osborne, A. R. 2010 Nonlinear Ocean Waves and the Inverse Scattering Transform, Int. Geophysics Ser., 97, Academic.Google Scholar
Peregrine, D. H. 1983 Water waves, nonlinear Schrodinger equations and their solutions. J. Austral. Math. Soc. Ser. B 25, 1643.Google Scholar
Ruban, V. 2011 Enhanced rise of rogue waves in slant wave groups. J. Expl Theor. Phys. Lett. 94, 194198.Google Scholar
Schober, C. M. 2006 Melnikov analysis and inverse spectral analysis of rogue waves in deep water. Eur. J. Mech. (B/Fluids) 25, 602620.CrossRefGoogle Scholar
Schober, C. M. & Calini, A. 2008 Rogue waves in higher-order nonlinear Schrodinger models. In Extreme Waves (ed. Pelinovsky, E. & Kharif, C.), pp. 3152. Springer.Google Scholar
Shemer, L. & Alperovich, L. 2013 Peregrine breather revisited. Phys. Fluids 25, 051701.CrossRefGoogle Scholar
Shrira, V. I. & Geogjaev, V. V. 2010 What makes the Peregrine soliton so special as a prototype of freak waves? J. Engng Maths 67, 1122.Google Scholar
Slunyaev, A. V. 2005 A high-order nonlinear envelope equation for gravity waves in finite-depth water. J. Expl Theor. Phys. 101, 926941.Google Scholar
Slunyaev, A. 2006 Nonlinear analysis and simulations of measured freak wave time series. Eur. J. Mech. (B/Fluids) 25, 621635.Google Scholar
Slunyaev, A. V. 2009 Numerical simulation of ‘limiting’ envelope solitons of gravity waves on deep water. J. Expl Theor. Phys. 109, 676686.CrossRefGoogle Scholar
Slunyaev, A. 2010 Freak wave events and the wave phase coherence. Eur. Phys. J. Special Topics 185, 6780.Google Scholar
Slunyaev, A., Clauss, G. F., Klein, M. & Onorato, M. 2013a Laboratory tests of short intense envelope solitons. Phys. Fluids 25, 067105.CrossRefGoogle Scholar
Slunyaev, A., Kharif, C., Pelinovsky, E. & Talipova, T. 2002 Nonlinear wave focusing on water of finite depth. Physica D 173, 7796.Google Scholar
Slunyaev, A., Pelinovsky, E., Sergeeva, A., Chabchoub, A., Hoffmann, N., Onorato, M. & Akhmediev, N. 2013b Super rogue waves in simulations based on weakly nonlinear and fully nonlinear hydrodynamic equations. Phys. Rev. E 88, 012909.Google Scholar
Slunyaev, A. V., Sergeeva, A. V. & Pelinovsky, E. N. et al. 2012 Modelling of deep-water rogue waves: different frameworks. In CENTEC Anniversary Book. Marine Technology and Engineering (ed. Guedes Soares, C.), pp. 199216. Taylor & Francis Group.Google Scholar
Stiassnie, M. & Shemer, L. 1984 On modifications of the Zakharov equation for surface gravity waves. J. Fluid Mech. 143, 4767.Google Scholar
Song, J.-B. & Banner, M. L. 2002 On determining the onset and strength of breaking for deep water waves. Part I: unforced irrotational wave groups. J. Phys. Oceanogr. 32, 25412558.Google Scholar
Tanaka, M. 1990 Maximum amplitude of modulated wavetrain. Wave Motion 12, 559568.Google Scholar
Trulsen, K. 2006 Weakly nonlinear and stochastic properties of ocean wave fields: application to an extreme wave event. In Waves in Geophysical Fluids: Tsunamis, Rogue Waves, Internal Waves and Internal Tides (ed. Grue, J. & Trulsen, K.), CISM Courses and Lectures, 489, Springer.Google Scholar
Trulsen, K. & Dysthe, K. B. 1996 A modified nonlinear Schrödinger equation for broader bandwidth gravity waves on deep water. Wave Motion 24, 281289.Google Scholar
Yuen, H. C. & Lake, B. M. 1982 Nonlinear dynamics of deep-water gravity waves. Adv. Appl. Mech. 22, 67327.Google Scholar
West, B. J., Brueckner, K. A., Janda, R. S., Milder, D. M. & Milton, R. L. 1987 A new numerical method for surface hydrodynamics. J. Geophys. Res. 92, 1180311824.Google Scholar
Whitham, G. B. 1974 Linear and Nonlinear Waves. Wiley.Google Scholar
Zakharov, V. 1968 Stability of periodic waves of finite amplitude on a surface of deep fluid. J. Appl. Mech. Tech. Phys. 2, 190194.Google Scholar
Zakharov, V. E., Dyachenko, A. I. & Vasilyev, O. A. 2002 New method for numerical simulation of a nonstationary potential flow of incompressible fluid with a free surface. Eur. J. Mech. (B/Fluids) 21, 283291.Google Scholar
Zakharov, V. E. & Ostrovsky, L. A. 2009 Modulation instability: the beginning. Physica D 238, 540548.Google Scholar
Zakharov, V. E. & Shabat, A. B. 1972 Exact theory of two-dimensional self-focusing and one-dimensional self-modulation of waves in nonlinear media. Sov. Phys. JETP 34, 6269.Google Scholar