Nonlinear Internal Waves in Synthetic Aperture Radar Imagery

Jackson, Christopher; Silva, José António Pereira da; Jeans, Gus; Alpers, Werner; Caruso, Michael J.

doi:10.5670/oceanog.2013.32

Cited by 65 publications

(42 citation statements)

References 9 publications

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“…Only this time, the upper velocity field is reversed in relation to the lower velocities, and hence in relation to typical mode-1 ISWs. In turn, this eventually means that the polarity of a mode-2 ISW-like wave signature at the surface is also reversed, meaning a dark reduced backscatter will precede bright enhanced backscatter in the propagation direction of the wave (see e.g., [2,26] for more details). The information retrieved from SAR imagery can be analysed together with in situ data and linear theory to provide further insights into the generation and propagation details.…”

Section: Acquisitionmentioning

confidence: 99%

Internal Solitary Waves in the Andaman Sea: New Insights from SAR Imagery

Magalhaes

Silva

2018

Remote Sensing

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The Andaman Sea in the Indian Ocean has been a classical study region for Internal Solitary Waves (ISWs) for several decades. Papers such as Osborne and Burch (1980) usually describe mode-1 packets of ISWs propagating eastwards, separated by distances of around 100 km. In this paper, we report on shorter period solitary-like waves that are consistent with a mode-2 vertical structure, which are observed along the Ten Degree Channel, and propagate side-by-side the usual large mode-1 solitary wave packets. The mode-2 waves are identified in TerraSAR-X images because of their distinct surface signatures, which are reversed when compared to those that are typical of mode-1 ISWs in the ocean. These newly observed regularly-spaced packets of ISW-like waves are characterized by average separations of roughly 30 km, which are far from the nominal mode-1 or even the mode-2 internal tidal wavelengths. On some occasions, five consecutive and regularly spaced mode-2 ISW-like wave envelopes were observed simultaneously in the same TerraSAR-X image. This fact points to a tidal generation mechanism somewhere in the west shallow ridges, south of the Nicobar Islands. Furthermore, it implies that unusually long-lived mode-2 waves can be found throughout the majority of the fortnightly tidal cycle. Ray tracing techniques are used to identify internal tidal beams as a possible explanation for the generation of the mode-2 solitary-like waves when the internal tidal beam interacts with the ocean pycnocline. Linear theory suggests that resonant coupling with long internal waves of higher-mode could explain the longevity of the mode-2 waves, which propagate for more than 100 km. Owing to their small-scale dimensions, the mode-2 waves may have been overlooked in previous remote sensing images. The enhanced radiometric resolution of the TerraSAR-X, alongside its wide coverage and detailed spatial resolutions, make it an ideal observational tool for the present study.

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Section: Acquisitionmentioning

confidence: 99%

Internal Solitary Waves in the Andaman Sea: New Insights from SAR Imagery

Magalhaes

Silva

2018

Remote Sensing

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“…Observations of internal waves with curvilinear fronts have been reported in several studies, e.g. Farmer & Armi (1988), Nash & Moum (2005) and Jackson et al (2013). Internal waves have a strong effect on acoustic signalling, as well as impacting submersibles, offshore structures and underwater pipelines.…”

Section: Introductionmentioning

confidence: 95%

Long ring waves in a stratified fluid over a shear flow

Хуснутдинова

Zhang

2016

J. Fluid Mech.

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Oceanic waves registered by satellite observations often have curvilinear fronts and propagate over various currents. In this paper we study long linear and weakly nonlinear ring waves in a stratified fluid in the presence of a depth-dependent horizontal shear flow. It is shown that, despite the clashing geometries of the waves and the shear flow, there exists a linear modal decomposition (different from the known decomposition in Cartesian geometry), which can be used to describe distortion of the wavefronts of surface and internal waves, and systematically derive a 2+1-dimensional cylindrical Korteweg-de Vries-type equation for the amplitudes of the waves. The general theory is applied to the case of the waves in a two-layer fluid with a piecewise-constant current, with an emphasis on the effect of the shear flow on the geometry of the wavefronts. The distortion of the wavefronts is described by the singular solution (envelope of the general solution) of the nonlinear first-order differential equation, constituting generalisation of the dispersion relation in this curvilinear geometry. There exists a striking difference in the shapes of the wavefronts of surface and interfacial waves propagating over the same shear flow.

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“…Farmer & Armi (1988), Morozov et al (2003), Palmer, Inall & Sharples (2013), remote sensing studies, e.g. Nash & Moum (2005), Jackson et al (2013), Grue (2013a), and laboratory experiments, e.g. Maxworthy (1979).…”

Section: Introductionmentioning

confidence: 99%

Nonlinear interfacial wave formation in three dimensions

Grue

2015

J. Fluid Mech.

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A three-dimensional two-layer, fully dispersive and strongly nonlinear interfacial wave model, including the interaction with a time-varying bottom topography, is developed. The method is based on a set of integral equations. The source and dipole terms are developed in series expansions in the vertical excursions of the interface and bottom topography, obtaining explicit inversion by Fourier transform. Calculations of strongly nonlinear interfacial waves with excursions comparable to the thinner layer depth show that the quadratic approximation of the method contains the essential dynamics, while the additional cubic terms always are small. Computations confirm the onset of wave train formation driven by topography, observed in experiments (Maxworthy, J. Geophys. Res., vol. 84(C1), 1979, pp. 338-346), depending on the Froude number and the topography height. Simulations of tidally driven three-dimensional internal wave formation show the formation of two wave trains per half tidal cycle for strong forcing and one wave train for weak forcing. Waves of both backward and forward curvature are calculated.

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Nonlinear Internal Waves in Synthetic Aperture Radar Imagery

Cited by 65 publications

References 9 publications

Internal Solitary Waves in the Andaman Sea: New Insights from SAR Imagery

Internal Solitary Waves in the Andaman Sea: New Insights from SAR Imagery

Long ring waves in a stratified fluid over a shear flow

Nonlinear interfacial wave formation in three dimensions

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