Experimental study of particle trajectories below deep-water surface gravity wave groups

Bremer, Ton S. van den; Whittaker, Colin; Calvert, Ross; Raby, Alison; Taylor, Paul C.J.

doi:10.1017/jfm.2019.584

Cited by 25 publications

(33 citation statements)

References 46 publications

(49 reference statements)

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“…We also carry out new particle tracking velocimetry (PTV) experiments for wavepackets in a laboratory wave flume in the finite-depth regime, in which the effect of set-down on Lagrangian particle displacement becomes significant. We thus extend results for deep-water for which the set-down can be ignored, obtained by van den Bremer et al [43], to finite depth for which it cannot. We measure the set-down, take into account the effect of error waves, extract the Lagrangian displacement and compare results with our theoretical predictions, finding good agreement.…”

Section: Introductionsupporting

confidence: 75%

“…In addition to the solutions to the irrotational water wave equations [35,36], streaming in the boundary layers [33,37,38], convection of vorticity from the ends of the tank into the interior of the fluid [37,39] (or conduction from the free surface and bottom boundary layers [40]) or enhanced transport for particles on the surface in breaking waves may play a role [34,41,42]. Recently, van den Bremer et al [43] have demonstrated experimentally that Lagrangian transport by the combination of Stokes drift and the Eulerian return flow underneath uni-directional, deep-water surface gravity wavepackets is in good agreement with leading-order solutions to the irrotational water wave equations. This paper derives solutions for the mean flow and the wave-averaged free surface using the multiple-scales method, which are valid in arbitrary depths relative to the scale of the packet and the Eulerian return flow.…”

Section: Introductionmentioning

confidence: 99%

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Laboratory study of the wave-induced mean flow and set-down in unidirectional surface gravity wave packets on finite water depth

et al. 2019

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The net movement of Lagrangian particles under water waves comprises a Stokes drift in the direction of wave propagation and an Eulerian return flow in the opposing direction. Accurate prediction of the Eulerian return flow in the ocean is of importance in modelling the transport of plastic pollution, oil, wreckage, and sediment. Herein, we derive a multiple-scales solution for the Eulerian mean flow under wavepackets that is valid for all water depths, both relative to the length of the wave and the length of the wavepacket. To validate this solution, we carry out Particle Tracking Velocimetry experiments in a long flume to extract the mean motion from Lagrangian seeding particles under wavepackets, finding good agreement. The extraction technique is able to deal with small background motion and sub-harmonic error waves associated with wave generation by the paddle, the latter being relatively large in finite-depth flume experiments. In finite depth, the return flow is forced by both the divergence of the Stokes transport on the wavepacket scale and the formation of a non-negligible mean set-down underneath the packet, which acts like a bounding streamtube in the form of a convergent-divergent duct. The magnitude of the horizontal return flow is thus enhanced, with particular relevance to transport in the finite-depth coastal environment.

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Section: Introductionsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Laboratory study of the wave-induced mean flow and set-down in unidirectional surface gravity wave packets on finite water depth

et al. 2019

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“…The results in van den Bremer et al (2019) may not be the last word on this topic. In 1802 Gerstner used the Lagrangian momentum equations to derive an exact solution to the inviscid water wave problem valid up to and including the deformed free surface (Gerstner 1802).…”

Section: Futurementioning

confidence: 95%

“…Given that the theory behind the Stokes drift is 172 years old, it is striking that the recent paper by van den Bremer et al (2019) is the first definitive, quantitative and unambiguous demonstration that the mean Lagrangian velocity in the absence of other flows can be accurately calculated from the lowest-order irrotational wave velocity field.…”

Section: Overviewmentioning

confidence: 99%

Stokes drift: theory and experiments

Monismith

2019

J. Fluid Mech.

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“…The wave‐induced particle drift has been studied experimentally in different works (i.e., Calvert et al., 2019; Grue & Koolas, 2017; Lenain et al., 2019; Paprota et al, 2016; van den Bremer et al., 2019) although there is still some confusion about the experimental measurement of the net wave‐induced drift at the interior of the fluid (Monismith et al., 2007; van den Bremer & Breivik, 2017). In a closed tank, the Stokes drift of a periodic wave train must be accompanied by a Eulerian return current so that the steady‐state depth‐integrated Lagrangian drift is zero.…”

Section: Introductionmentioning

confidence: 99%

Laboratory Measurements of the Wave‐Induced Motion of Plastic Particles: Influence of Wave Period, Plastic Size and Plastic Density

2020

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The amount of plastic in the aquatic environment is rapidly growing, with plastic litter having been reported in almost every marine environment. Understanding plastic dispersion is a key knowledge gap for plastic litter management and cleaning. It is widely assumed that the main source of plastic litter to the oceans is terrestrial and, therefore, the dominant plastic pathway from land sources to the ocean is via coastal regions. However, although there is relatively good knowledge on how the plastic particles move by oceanic currents, it is not clear how the plastic particles are transported by highly nonlinear coastal waves (see van Sebille et al., 2020, for a recent review on the physical plastic transport). Indeed, most of the existing global numerical models predicting plastic fluxes do not explicitly consider the plastic motion in coastal regions including the potential plastic beaching (i.e., plastic being washed ashore) (Neumann et al., 2014). The hydrodynamics controlling the motion of plastic in intermediate and shallow water is dominated by nonlinear gravity waves propagating toward the shoreline (wave motions and wave-induced currents). A particle floating on the free surface of a periodic gravity wave experiences a net drift in the direction of wave propagation termed Stokes drift (Stokes, 1847). The Stokes drift velocity is explained by the difference between the average Lagrangian velocity experienced by the particle and the average Eulerian flow velocity of the fluid (Longuet-Higgins, 1953; van den Bremer & Breivik, 2017). The Stokes drift is a second order velocity (Longuet-Higgins, 1953) of smaller magnitude than the magnitude of the wave orbital motion but,

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Experimental study of particle trajectories below deep-water surface gravity wave groups

Cited by 25 publications

References 46 publications

Laboratory study of the wave-induced mean flow and set-down in unidirectional surface gravity wave packets on finite water depth

Laboratory study of the wave-induced mean flow and set-down in unidirectional surface gravity wave packets on finite water depth

Stokes drift: theory and experiments

Laboratory Measurements of the Wave‐Induced Motion of Plastic Particles: Influence of Wave Period, Plastic Size and Plastic Density

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