Shoaling mode-2 internal solitary-like waves

The propagation of a train of mode-2 internal solitary-like waves (ISWs) over a uniformly sloping, solid topographic boundary, has been studied by means of a combined laboratory and numerical investigation. The waves are generated by a lock-release method. Features of their shoaling include (i) form...

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Bibliographic Details
Published inJournal of fluid mechanics Vol. 879; pp. 604 - 632
Main Authors Carr, Magda, Stastna, Marek, Davies, Peter A., van de Wal, Koen J.
Format Journal Article
LanguageEnglish
Published Cambridge Cambridge University Press 25.11.2019
Subjects
Boundary layers
Computational fluid dynamics
Degeneration
Elevation
Flow separation
Fluid flow
Fluids
Gravity
Laboratories
Microgravity
Pycnocline
Reflected waves
Reynolds number
Separation
Shoaling
Slopes
Studies
Topography
Velocity
Wave amplitude
Wave propagation
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Summary:The propagation of a train of mode-2 internal solitary-like waves (ISWs) over a uniformly sloping, solid topographic boundary, has been studied by means of a combined laboratory and numerical investigation. The waves are generated by a lock-release method. Features of their shoaling include (i) formation of an oscillatory tail, (ii) degeneration of the wave form, (iii) wave run up, (iv) boundary layer separation, (v) vortex formation and re-suspension at the bed and (vi) a reflected wave signal. Slope steepness, $s$ , is defined to be the height of the slope divided by the slope base length. In shallow slope cases ( $s\leqslant 0.07$ ), the wave form is destroyed by the shoaling process; the leading mode-2 ISW degenerates into a train of mode-1 waves of elevation and little boundary layer activity is seen. For steeper slopes ( $s\geqslant 0.13$ ), boundary layer separation, vortex formation and re-suspension at the bed are observed. The boundary layer dynamics is shown (numerically) to be dependent on the Reynolds number of the flow. A reflected mode-2 wave signal and wave run up are seen for slopes of steepness $s\geqslant 0.20$ . The wave run up distance is shown to be proportional to the length scale $ac^{2}/g^{\prime }h_{2}\sin \unicode[STIX]{x1D703}$ where $a,c,g^{\prime },h_{2}$ and $\unicode[STIX]{x1D703}$ are wave amplitude, wave speed, reduced gravity, pycnocline thickness and slope angle respectively.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2019.671