Your search keyword '"Souza, Alejandro J."' showing total 24 results

1. Small Scale Bedform Types off the South-Holland Coast

Author

Meirelles, Saulo, Henriquez, Martijn, Souza, Alejandro J., Horner-Devine, Alexander R., Pietrzak, Julie D., Rijnsburg, Sabine, and Stive, Marcel J. F.

Published

2016

2. Fate and pathways of dredged estuarine sediment spoil in response to variable sediment size and baroclinic coastal circulation

Author

Brown, Jennifer M., Amoudry, Laurent O., Souza, Alejandro J., and Rees, Jon

Published

2015

3. Behaviour influences larval dispersal in shelf sea gyres : Nephrops norvegicus in the Irish Sea

Author

Phelps, Jack J. C., Polton, Jeff A., Souza, Alejandro J., and Robinson, Leonie A.

Published

2015

4. On the Advection of Upwelled Water on the Western Yucatan Shelf

Author

Kurczyn, Jorge. A., primary, Duran, Rodrigo, additional, Beier, Emilio, additional, and Souza, Alejandro J., additional

Published

2021

5. The Evolution of Plume Fronts in the Rhine Region of Freshwater Influence

Author

Rijnsburger, S. (author), Flores, Raúl P. (author), Pietrzak, J.D. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Zijl, Firmijn (author), Rijnsburger, S. (author), Flores, Raúl P. (author), Pietrzak, J.D. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), and Zijl, Firmijn (author)

Abstract

The Rhine region of freshwater influence (ROFI) is strongly stratified, rotational, relatively shallow and has large tides, resulting in a dynamic field of fronts that are formed by multiple processes. We use a 3D numerical model to obtain a conceptual picture of the frontal structure and the processes responsible for generating this multiple front structure in the Rhine ROFI. The horizontal salinity gradient and numerical tracers are used to identify three different types of fronts: outer, inner, tidal plume and relic tidal plume fronts. Tidal plume front (TPF) trajectories together with the tracers demonstrate that TPFs exist for longer than one tidal cycle. A Lagrangian frontogenesis analysis shows that the fronts are strengthened mainly as a result of increased convergence, which is observed to occur at times when tidal straining is large. Additionally the alongshore tidal excursion and the dominance of the tidal currents over the intrinsic frontal propagation speed, trap TPFs within 20 km from the river mouth. Trapping and re-strengthening maintain several fronts at a time in the mid-field region, resulting in a multi-frontal system. The observation of a complex river plume system is expected to be important for cross-shore exchange, transport and coastal ecology., Environmental Fluid Mechanics

Published

2021

6. Observations of Multiple Internal Wave Packets in a Tidal River Plume

Author

Rijnsburger, S. (author), Flores, Raúl P. (author), Pietrzak, J.D. (author), Lamb, Kevin G. (author), Jones, Nicole L. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Rijnsburger, S. (author), Flores, Raúl P. (author), Pietrzak, J.D. (author), Lamb, Kevin G. (author), Jones, Nicole L. (author), Horner-Devine, Alexander R. (author), and Souza, Alejandro J. (author)

Abstract

Remotely sensed images document the occurrence of multiple packets of internal solitary waves (ISWs) in the Rhine River plume at the same time. We use a combination of field observations, and non-hydrostatic and hydrostatic modeling to understand the processes that lead to the generation and retention of multiple ISW packets within the Rhine plume. Previous numerical modeling shows that the tidal plume front is trapped in the mid-field plume for more than one tidal cycle due to tidal straining and recirculation within the plume, resulting in the presence of multiple fronts in the near-and mid-field plume regions. In this work, we show how variations in the strength of these fronts can lead to the release of ISW packets. We conclude that the retention of the fronts in the mid-field region of the plume and modulation in the strength of the fronts can explain the presence of multiple ISW packets. A frontal Froude number analysis shows that fronts generated during the previous ebb tide can release ISWs in addition to the newly released tidal plume front., Environmental Fluid Mechanics

Published

2021

7. The formation of turbidity maximum zones by minor axis tidal straining in regions of freshwater influence

Author

Flores, Raúl P. (author), Rijnsburger, S. (author), Horner-Devine, Alexander R. (author), Kumar, Nirnimesh (author), Souza, Alejandro J. (author), Pietrzak, J.D. (author), Flores, Raúl P. (author), Rijnsburger, S. (author), Horner-Devine, Alexander R. (author), Kumar, Nirnimesh (author), Souza, Alejandro J. (author), and Pietrzak, J.D. (author)

Abstract

This study investigates the influence of tidal straining in the generation of turbidity maximum zones (TMZ), which are observed to extend for tens of kilometers along some shallow, open coastal seas. Idealized numerical simulations are conducted to reproduce the cross-shore dynamics and tidal straining in regions of freshwater influence (ROFIs), where elliptical current patterns are generated by the interaction between stratification and a tidal Kelvin wave. Model results show that tidal straining leads to cross-shore sediment convergence and the formation of a nearshore TMZ that is detached from the coastline. The subtidal landward sediment fluxes are created by asymmetries in vertical mixing between the stratifying and destratifying phases of the tidal cycle. This process is similar to the tidal straining mechanism that is observed in estuaries, except that in this case the convergence zone and TMZ are parallel to the shoreline and perpendicular to both the direction of the freshwater flux and the major axis of the tidal flow. We introduce the term minor axis tidal straining (MITS) to describe the tidal straining in these systems and to differentiate it from the tidal straining that occurs when the major axis of the tidal ellipse is aligned with the density gradient. The occurrence of tidal straining and the coastal TMZ is predicted in terms of the Simpson (Si) and Stokes (Stk) numbers, and top–bottom tidal ellipticity difference (∆ε). Based on our results, we find that SiStk2 > 3 and ∆ε > 0.5 provide a limiting condition for the required density gradients and latitudes for the occurrence of MITS and the generation of a TMZ., Environmental Fluid Mechanics

Published

2020

8. The Formation of Turbidity Maximum Zones by Minor Axis Tidal Straining in Regions of Freshwater Influence

Author

Flores, Raúl P., primary, Rijnsburger, Sabine, additional, Horner-Devine, Alexander R., additional, Kumar, Nirnimesh, additional, Souza, Alejandro J., additional, and Pietrzak, Julie D., additional

Published

2020

9. Observations of internal waves in the near field of the Rhine River Plume

Author

Rijnsburger, S., Audibert, Raul Flores, Pietrzak, J.D., Horner-Devine, Alexander, Souza, Alejandro J., Jones, Nicole, and Lamb, Kevin

Published

2019

10. Observations of internal waves in the near field of the Rhine River Plume

Author

Rijnsburger, S. (author), Audibert, Raul Flores (author), Pietrzak, J.D. (author), Horner-Devine, Alexander (author), Souza, Alejandro J. (author), Jones, Nicole (author), Lamb, Kevin (author), Rijnsburger, S. (author), Audibert, Raul Flores (author), Pietrzak, J.D. (author), Horner-Devine, Alexander (author), Souza, Alejandro J. (author), Jones, Nicole (author), and Lamb, Kevin (author)

Abstract

Environmental Fluid Mechanics

Published

2019

11. Wave Generation of Gravity-Driven Sediment Flows on a Predominantly Sandy Seabed

Author

Flores, Raúl P. (author), Rijnsburger, S. (author), Meirelles, Saulo (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Pietrzak, J.D. (author), Henriquez, M. (author), Reniers, A.J.H.M. (author), Flores, Raúl P. (author), Rijnsburger, S. (author), Meirelles, Saulo (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Pietrzak, J.D. (author), Henriquez, M. (author), and Reniers, A.J.H.M. (author)

Abstract

Wave-supported gravity flows (WSGFs) generate rates of sediment flux far exceeding other cross-shelf transport processes, contributing disproportionately to shelf morphology and net cross-shelf fluxes of sediment in many regions worldwide. However, the conditions deemed necessary for the formation of WSGF limit them to a narrow set of shelf conditions; they have been observed exclusively in regions where the seabed consists of very fine-grained sediment and typically co-occur with nearby river flood events. Here we document the occurrence of a WSGF event on a predominantly sandy seabed and in the absence of a preceding river flood. Our measurements confirm that the dynamics are governed by the friction-buoyancy balance observed in other WSGF and that WSGF can form in mixed grain-size environments and transport high concentrations of sand. The occurrence of WSGF on a predominantly sandy seabed suggests that they may occur under a much wider range of conditions and, given the global prevalence of sandy shelves, they may be a more frequent and more ubiquitous feature of shelf dynamics than previously thought., Environmental Fluid Mechanics, Coastal Engineering

Published

2018

12. Cross-shore stratified tidal flow seaward of a mega-nourishment

Author

Meirelles, Saulo (author), Henriquez, M. (author), Reniers, A.J.H.M. (author), Luijendijk, A.P. (author), Pietrzak, J.D. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Stive, M.J.F. (author), Meirelles, Saulo (author), Henriquez, M. (author), Reniers, A.J.H.M. (author), Luijendijk, A.P. (author), Pietrzak, J.D. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), and Stive, M.J.F. (author)

Abstract

The Sand Engine is a 21.5 million m3 experimental mega-nourishment project that was built in 2011 along the Dutch coast. This intervention created a discontinuity in the previous straight sandy coastline, altering the local hydrodynamics in a region that is influenced by the buoyant plume generated by the Rhine River. This work investigates the response of the cross-shore stratified tidal flow to the coastal protrusion created by the Sand Engine emplacement by using a 13 h velocity and density survey. Observations document the development of strong baroclinic-induced cross-shore exchange currents dictated by the intrusion of the river plume fronts as well as the classic tidal straining which are found to extend further into the nearshore (from 12 to 6m depth), otherwise believed to be a mixed zone. Estimates of the centrifugal acceleration directly after construction of the Sand Engine showed that the curvature effects were approximately 2 times stronger, suggesting that the Sand Engine might have played a role in controlling the cross-shore exchange currents during the first three years after the completion of the nourishment. Presently, the curvature effects are minute., Coastal Engineering, Environmental Fluid Mechanics

Published

2018

13. The Influence of Tide and Wind on the Propagation of Fronts in a Shallow River Plume

Author

Rijnsburger, S. (author), Flores, Raúl P. (author), Pietrzak, J.D. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Rijnsburger, S. (author), Flores, Raúl P. (author), Pietrzak, J.D. (author), Horner-Devine, Alexander R. (author), and Souza, Alejandro J. (author)

Abstract

In this study we used field data and radar images to investigate the influence of winds and tides on the propagation of tidal plume fronts. The measurements were collected in a shallow shelf region off the Dutch coast, 10 km north of the Rhine River mouth, and they clearly show the passage of distinct freshwater lenses and associated fronts at the surface that propagate all the way to the coastline. These fronts are observed as a sudden drop in near-surface salinity, accompanied by high cross-shore shear with onshore velocities at the surface. We determined the arrival time to our measurement site, frontal propagation speed, and structure of the fronts by combining the in situ data and radar images. Frontal Froude numbers show a wide range of values, with an average of 0.44. Our results show that fronts during spring tides are thinner, more mixed, and move faster relative to the ground during calm spring tides when compared to calm neap tides. Downwelling winds during spring tides result in thicker and faster fronts; however, the intrinsic frontal propagation speed indicates that the wind and tide control the frontal propagation mainly due to advection rather than by changing the frontal structure. Strong return currents in the near-bed layer resulting from fast and thick fronts increase near-bed turbulence and bed stresses. These high stresses suggest that the passage of fronts in shallow coastal areas can initiate sediment resuspension and contribute to transport processes., Environmental Fluid Mechanics

Published

2018

14. Cross-shore stratified tidal flow seaward of a mega-nourishment

Author

Meirelles, Saulo, Henriquez, Martijn, Reniers, Ad, Luijendijk, Arjen P., Pietrzak, Julie, Horner-Devine, Alexander R., Souza, Alejandro J., Stive, Marcel J.F., Meirelles, Saulo, Henriquez, Martijn, Reniers, Ad, Luijendijk, Arjen P., Pietrzak, Julie, Horner-Devine, Alexander R., Souza, Alejandro J., and Stive, Marcel J.F.

Abstract

The Sand Engine is a 21.5 million m3 experimental mega-nourishment project that was built in 2011 along the Dutch coast. This intervention created a discontinuity in the previous straight sandy coastline, altering the local hydrodynamics in a region that is in influenced by the buoyant plume generated by the Rhine River. This work investigates the response of the cross-shore stratified tidal flow to the coastal protrusion created by the Sand Engine emplacement by using a 13 hour velocity and density survey. Observations document the development of strong baroclinic-induced cross-shore exchange currents dictated by the intrusion of the river plume fronts as well as the classic tidal straining which are found to extend further into the nearshore (from 12 to 6m depth), otherwise believed to be a mixed zone.

Published

2018

15. Wave Generation of Gravity‐Driven Sediment Flows on a Predominantly Sandy Seabed

Author

Flores, Raúl P., primary, Rijnsburger, Sabine, additional, Meirelles, Saulo, additional, Horner‐Devine, Alexander R., additional, Souza, Alejandro J., additional, Pietrzak, Julie D., additional, Henriquez, Martijn, additional, and Reniers, Ad, additional

Published

2018

16. Cross-shore transport of nearshore sediment by river plume frontal pumping

Author

Horner-Devine, Alexander R., Pietrzak, Julie D., Souza, Alejandro J., McKeon, Margaret A., Meirelles, Saulo, Henriquez, Martijn, Flores, Raúl P., Rijnsburger, Sabine, Horner-Devine, Alexander R., Pietrzak, Julie D., Souza, Alejandro J., McKeon, Margaret A., Meirelles, Saulo, Henriquez, Martijn, Flores, Raúl P., and Rijnsburger, Sabine

Abstract

We present a new mechanism for cross-shore transport of fine sediment from the nearshore to the inner shelf resulting from the onshore propagation of river plume fronts. Onshore frontal propagation is observed in moorings and radar images, which show that fronts penetrate onshore through the nearshore and surf zone, almost to the waterline. During frontal passage a two-layer counterrotating velocity field characteristic of tidal straining is immediately set up, generating a net offshore flow beneath the plume. The seaward flow at depth carries with it high suspended sediment concentrations, which appear to have been generated by wave resuspension in the nearshore region. These observations describe a mechanism by which vertical density stratification can drive exchange of material between the nearshore region and the inner shelf. To our knowledge these are the first observations of this frontal pumping mechanism, which is expected to play an important role in sediment transport near river mouths.

Published

2017

17. Cross-shore transport of nearshore sediment by river plume frontal pumping

Author

Horner-Devine, Alexander R. (author), Pietrzak, J.D. (author), Souza, Alejandro J. (author), McKeon, Margaret A. (author), Meirelles, Saulo (author), Henriquez, M. (author), Flores, Raúl P. (author), Rijnsburger, S. (author), Horner-Devine, Alexander R. (author), Pietrzak, J.D. (author), Souza, Alejandro J. (author), McKeon, Margaret A. (author), Meirelles, Saulo (author), Henriquez, M. (author), Flores, Raúl P. (author), and Rijnsburger, S. (author)

Abstract

We present a new mechanism for cross-shore transport of fine sediment from the nearshore to the inner shelf resulting from the onshore propagation of river plume fronts. Onshore frontal propagation is observed in moorings and radar images, which show that fronts penetrate onshore through the nearshore and surf zone, almost to the waterline. During frontal passage a two-layer counterrotating velocity field characteristic of tidal straining is immediately set up, generating a net offshore flow beneath the plume. The seaward flow at depth carries with it high suspended sediment concentrations, which appear to have been generated by wave resuspension in the nearshore region. These observations describe a mechanism by which vertical density stratification can drive exchange of material between the nearshore region and the inner shelf. To our knowledge these are the first observations of this frontal pumping mechanism, which is expected to play an important role in sediment transport near river mouths., Environmental Fluid Mechanics, Coastal Engineering

Published

2017

18. The impact of storms and stratification on sediment transport in the Rhine region of freshwater influence

Author

Flores, Raúl P. (author), Rijnsburger, S. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), Pietrzak, J.D. (author), Flores, Raúl P. (author), Rijnsburger, S. (author), Horner-Devine, Alexander R. (author), Souza, Alejandro J. (author), and Pietrzak, J.D. (author)

Abstract

We present measurements of along and across-shore sediment transport in a region of the Dutch coast 10 km north of the Rhine River mouth. This section of the coast is characterized by strong vertical density stratification because it is within the midfield region of the Rhine region of freshwater influence, where processes typical of the far-field, such as tidal straining, are modified by the passage of distinct freshwater lenses at the surface. The experiment captured two storms, and a wide range of wind, wave, tidal and stratification conditions. We focus primarily on the mechanisms leading to cross-shore sediment flux at a mooring location in 12 m of water, which are responsible for the exchange of sediment between the nearshore and the inner shelf. Net transport during storms was directed offshore and influenced by cross-shelf winds, while net transport during spring tides was determined by the mean state of stratification. Tidal straining dominated during neap tides; however, cross-shore transport was negligible due to small sediment concentrations. The passage of freshwater lenses manifested as strong pulses of offshore transport primarily during spring tides. We observe that both barotropic and baroclinic processes are relevant for cross-shore transport at depth and, since transport rates due to these competing processes were similar, the net transport direction will be determined by the frequency and sequencing of these modes of transport. Based on our observations, we find that wind and wave-driven transport during storms tends move fine sediment offshore, while calmer, more stratified conditions move it back onshore., Environmental Fluid Mechanics

Published

2017

19. Hydrodynamics in the mid-field plume region of the Rhine ROFI

Author

Rijnsburger, S., Audibert, R.F., Souza, Alejandro J., Horner-Devine, Alexander R., and Pietrzak, J.D.

Subjects

frontal dynamics, cross-shore straining, numerical modelling, river plume, in-situ measurements

Abstract

River plumes, also regions of freshwater influence , are important features to understand because of their impact on the current structure, stratification and the transport of fine sediments, nutrients and contaminants. One important river plume is the Rhine ROFI. Prior studies have sought to understand far-field dynamics where cross-shore straining is dominant (Simpson & Souza, 1995; Souza & Simpson,1995; De Boer et al., 2008). However, less is known about the mid-field region of this river plume, where fronts matter as well. Here we use field observations from a 6 week measurement campaign in fall 2014 to investigate the dynamics of the mid-field region of het Rhine ROFI. We will focus on the interaction between far-field processes, such as tidal straining, and near field processes, such as fronts. The Rhine ROFI is of interest because the Dutch coast has been modified by extending the Port of Rotterdam and the construction of the Sand Engine that extends into the southern North Sea. These perturbations might impact the currents, the ROFI and the distribution of fine sediment, nutrients and contaminants. Therefore, the understanding of this is of importance. During September and October 2014, a large field observational campaign was conducted off the Dutch coast close to the sand Engine, 10 km north of the river outflow. Measurements were made at two locations, 2 and 5.5 km offshore (see Figure 1). Moorings, with Conductivity Temperature Depth (CTD) and Optical Backscatter (OBS) instruments at different depths, were deployed to obtain vertical profiles of salinity and suspended sediment concentrations (SSC). In addition, at each location a bottom-mounted Acoustic Doppler Current Profiler (ADCP) measured vertical velocity profiles. Radar images of the area were used to gain surface information, specifically about frontal propagation in the vicinity of the measurement locations. The weather conditions were highly variable during the six week period. There were very calm periods, but also storms, which completely destroyed stratification. The wind direction changed during the campaign as well. In addition to the data, numerical modelling with a 3D hydrostatic model will be used to gain information of the entire mid-field plume.

Published

2016

20. Cross‐shore transport of nearshore sediment by river plume frontal pumping

Author

Horner‐Devine, Alexander R., primary, Pietrzak, Julie D., additional, Souza, Alejandro J., additional, McKeon, Margaret A., additional, Meirelles, Saulo, additional, Henriquez, Martijn, additional, Flores, Raúl P., additional, and Rijnsburger, Sabine, additional

Published

2017

21. Hydrodynamics in the mid-field plume region of the Rhine ROFI

Author

Rijnsburger, S. (author), Audibert, R.F. (author), Souza, Alejandro J. (author), Horner-Devine, Alexander R. (author), Pietrzak, J.D. (author), Rijnsburger, S. (author), Audibert, R.F. (author), Souza, Alejandro J. (author), Horner-Devine, Alexander R. (author), and Pietrzak, J.D. (author)

Abstract

River plumes, also regions of freshwater influence , are important features to understand because of their impact on the current structure, stratification and the transport of fine sediments, nutrients and contaminants. One important river plume is the Rhine ROFI. Prior studies have sought to understand far-field dynamics where cross-shore straining is dominant (Simpson & Souza, 1995; Souza & Simpson,1995; De Boer et al., 2008). However, less is known about the mid-field region of this river plume, where fronts matter as well. Here we use field observations from a 6 week measurement campaign in fall 2014 to investigate the dynamics of the mid-field region of het Rhine ROFI. We will focus on the interaction between far-field processes, such as tidal straining, and near field processes, such as fronts. The Rhine ROFI is of interest because the Dutch coast has been modified by extending the Port of Rotterdam and the construction of the Sand Engine that extends into the southern North Sea. These perturbations might impact the currents, the ROFI and the distribution of fine sediment, nutrients and contaminants. Therefore, the understanding of this is of importance. During September and October 2014, a large field observational campaign was conducted off the Dutch coast close to the sand Engine, 10 km north of the river outflow. Measurements were made at two locations, 2 and 5.5 km offshore (see Figure 1). Moorings, with Conductivity Temperature Depth (CTD) and Optical Backscatter (OBS) instruments at different depths, were deployed to obtain vertical profiles of salinity and suspended sediment concentrations (SSC). In addition, at each location a bottom-mounted Acoustic Doppler Current Profiler (ADCP) measured vertical velocity profiles. Radar images of the area were used to gain surface information, specifically about frontal propagation in the vicinity of the measurement locations. The weather conditions were highly variable during the six week period. There we, Environmental Fluid Mechanics

Published

2016

22. Behaviour influences larval dispersal in shelf sea gyres: Nephrops norvegicus in the Irish Sea

Author

Phelps, Jack J.C., Polton, Jeff A., Souza, Alejandro J., Robinson, Leonie A, Phelps, Jack J.C., Polton, Jeff A., Souza, Alejandro J., and Robinson, Leonie A

Abstract

The western Irish Sea seasonal gyre is widely believed to play an important role in the local retention of resident larvae. This mechanism could be particularly crucial for the larvae of the heavily fished crustacean Nephrops norvegicus (L.), as their sediment requirements highly restrict where they are able to settle. As recent research suggests that the gyre may be becoming less retentive due to changes in atmospheric forcing, it is now crucial to understand how the gyre influences dispersal. This investigation addresses the hypothesis that shelf sea gyres reinforce larval retention using a biophysical model with vertical migration, habitat selection and temperature-dependent pelagic larval duration (PLD) configured to match the behaviour of N. norvegicus larvae. The results of this study suggest that the gyre does increase the likelihood that passive larvae remain within the western Irish Sea, on the condition that the larvae remain fixed at the depth of peak gyral flow. Retention rates are significantly lower when vertical migration is introduced, and there is no evidence that the gyre promotes larval retention amongst either vertically migrating larvae, or larvae that require muddy sediments for successful settlement. By contrast, vertical migration is shown to be favourable for retention in the eastern Irish Sea. PLD varies by a factor of two according to release date and location. The simulations suggest that whilst some highly limited and almost entirely unidirectional larval exchange may occur, the distinct sites largely rely upon local recruitment.

Published

2015

23. NEAR-BOTTOM CURRENTS ON THE MIDDLE SHOREFACE IN THE PRESENCE OF THE RHINE RIVER PLUME

Author

Henriquez, M., Meirelles, Saulo, Horner-Devine, Alexander R., Souza, Alejandro J., Pietrzak, J.D., Stive, M.J.F., and Lynett, Patrick J.

Subjects

geography, Tidal straining, geography.geographical_feature_category, Turbulence, Lower shoreface, Flow (psychology), Magnitude (mathematics), River plume, Sediment transport, Physics::Geophysics, Physics::Fluid Dynamics, Field measurements, Tidal bore, Fresh water, General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics, Geomorphology, Astrophysics::Galaxy Astrophysics, Physics::Atmospheric and Oceanic Physics, Geology, General Environmental Science

Abstract

The South-Holland coast of the Netherlands undergoes the influence of the Rhine river plume released from the Rotterdam waterways. An experiment, STRAINS, was conducted to study the impact of the fresh water on the nearshore hydrodynamics and sand transport. As part of the experiment, an instrumented bottom frame measured the near-bed hydrodynamics at 12 m depth. The flow was decomposed in the tidal, wave and turbulent component. During moderate energetic wave conditions the cross-shore tidal flow was of similar magnitude as the wave orbital flow. The cross-shore tidal flow was asymmetric and larger in the seaward direction. The cross-shore tidal component may be generated by tidal straining due to the river plume.

Published

2014

24. Middle shoreface sand transport under the influence of a river plume.

Author

Meirelles, Saulo, Horner-Devine, Alexander R., Henriquez, Martijn, Stive, Marcel, Pietrzak, Julie, and Souza, Alejandro J.

Subjects

COASTS, FRESH water, SHORELINES, TIDES, OCEAN waves

Abstract

Observations from a field experiment along the south-Holland coast, the Netherlands, were carried out in order to obtain new insights about the impacts of the Rhine ROFI (Region of Freshwater Influence) on the sand transport patterns. The net alongshore sand transport is generally governed by tides. The sediment concentration in the middle shoreface increased significantly with approaching waves of higher than ~1 m and Tm0 > 5 s. The southward net transport of the alongshore component does not agree with the literature. Modulations of the net cross-shore transport direction were observed. The net transport is more relevant during the neap tides where the velocity magnitudes are smaller. [ABSTRACT FROM AUTHOR]

Published

2014