2016
DOI: 10.1098/rspa.2015.0416
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Formation of wave packets in the Ostrovsky equation for both normal and anomalous dispersion

Abstract: It is well known that the Ostrovsky equation with normal dispersion does not support steady solitary waves. An initial Korteweg–de Vries solitary wave decays adiabatically through the radiation of long waves and is eventually replaced by an envelope solitary wave whose carrier wave and envelope move with different velocities (phase and group velocities correspondingly). Here, we examine the same initial condition for the Ostrovsky equation with anomalous dispersion, when the wave frequency increases with waven… Show more

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Cited by 28 publications
(52 citation statements)
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“…In this case the initial BO soliton does not decay, but gradually evolves into another soliton of a higher amplitude and zero mean value. A similar situation occurs for KdV solitons which gradually transform into Ostrovsky solitons under the influence of large scale dispersion [14]. In Fig.…”
Section: Extended Nonlinear Schrödinger Equationmentioning
confidence: 82%
“…In this case the initial BO soliton does not decay, but gradually evolves into another soliton of a higher amplitude and zero mean value. A similar situation occurs for KdV solitons which gradually transform into Ostrovsky solitons under the influence of large scale dispersion [14]. In Fig.…”
Section: Extended Nonlinear Schrödinger Equationmentioning
confidence: 82%
“…The variables and analysis of §3 give a context for discussing the emergence of the wavepacket solutions above from KdV soliton initial conditions under weak rotation as observed by Grimshaw & Helfrich [8], Grimshaw et al [7] and Whitfield & Johnson [9]. In terms of the variables (2.4), equation (2.1) has the inner solitary wave solution …”
Section: Wavepacket Emergencementioning
confidence: 99%
“…In the strong-rotation limit ( 1), these solutions originate from the point in wavenumber space where the linear phase and group velocities are equal [7], but as the strength of rotation is decreased the wavepacket structure of this family of solutions is eventually replaced by a soliton solution (figure 2a) that is described asymptotically by a KdV soliton with pedestal of order 1 [15]. Section 4 describes how these single-peak solitary wave solutions arise naturally from the evolution of an initial KdV soliton in the presence of weak rotation.…”
Section: Application To Wavepackets (A) Anomalous Dispersionmentioning
confidence: 99%
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