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Transverse Instability of Rogue Waves

Mark J. Ablowitz, Justin T. Cole

2021Physical Review Letters37 citationsDOIOpen Access PDF

Abstract

Rogue waves are abnormally large waves which appear unexpectedly and have attracted considerable attention, particularly in recent years. The one space, one time (1+1) nonlinear Schrödinger equation is often used to model rogue waves; it is an envelope description of plane waves and admits the so-called Pergerine and Kuznetov-Ma soliton solutions. However, in deep water waves and certain electromagnetic systems where there are two significant transverse dimensions, the 2+1 hyperbolic nonlinear Schrödinger equation is the appropriate wave envelope description. Here we show that these rogue wave solutions suffer from strong transverse instability at long and short frequencies. Moreover, the stability of the Peregrine soliton is found to coincide with that of the background plane wave. These results indicate that, when applicable, transverse dimensions must be taken into account when investigating rogue wave pheneomena.

Topics & Concepts

Rogue wavePhysicsTransverse planeSolitonInstabilityEnvelope (radar)Transverse wavePlane (geometry)Plane waveClassical mechanicsNonlinear systemNonlinear Schrödinger equationLongitudinal waveQuantum electrodynamicsWave propagationMechanicsQuantum mechanicsGeometryMathematicsTelecommunicationsStructural engineeringComputer scienceRadarEngineeringNonlinear Waves and SolitonsNonlinear Photonic SystemsAdvanced Fiber Laser Technologies
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