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203 results on '"Zijlema, Marcel"'

1. Including the effect of depth-uniform ambient currents on waves in a non-hydrostatic wave-flow model

Author

Rijnsdorp, Dirk P., van Rooijen, Arnold, Reniers, Ad, Tissier, Marion, de Wit, Floris, and Zijlema, Marcel

Subjects
Physics - Fluid Dynamics, Physics - Atmospheric and Oceanic Physics
Abstract

Currents can affect the evolution of waves in nearshore regions through altering their wavenumber and amplitude. Including the effect of ambient currents (e.g., tidal and wind-driven) on waves in phase-resolving wave models is not straightforward as it requires appropriate boundary conditions in combination with a large domain size and long simulation duration. In this paper, we extended the non-hydrostatic wave-flow model SWASH with additional terms that account for the influence of a depth-uniform ambient current on the wave dynamics, in which the current field can be taken from an external source (e.g., from observations or a circulation model). We verified the model ability by comparing predictions to results from linear theory, laboratory experiments and a spectral wave model that accounts for wave interference effects. With this extension, the model was able to account for current-induced changes to the wave field (i.e., changes to the wave amplitude, length and direction) due to following and opposing currents, and two classical examples of sheared currents (a jet-like current and vortex ring). Furthermore, the model captured the wave dynamics in the presence of strong opposing currents. This includes reflections of relatively small amplitude waves at the theoretical blocking point, and transmission of breaking waves beyond the theoretical blocking point for larger wave amplitudes. The proposed model extension allows phase-resolving models to more accurately and efficiently simulate the wave dynamics in coastal regions with tidal and/or wind-driven flows.

Published
2023

2. Non-hydrostatic modelling of the wave-induced response of moored floating structures

Author

Rijnsdorp, Dirk Pieter, Wolgamot, Hugh, and Zijlema, Marcel

Subjects
Physics - Atmospheric and Oceanic Physics, Physics - Fluid Dynamics
Abstract

Predictions of the wave-induced response of floating structures that are moored in a harbour or coastal waters require an accurate description of the (nonlinear) evolution of waves over variable bottom topography, the interactions of the waves with the structure, and the dynamics of the mooring system. In this paper, we present a new advanced numerical model to simulate the wave-induced response of a floating structure that is moored in an arbitrary nearshore region. The model is based on the non-hydrostatic approach, and implemented in the open-source model SWASH, which provides an efficient numerical framework to simulate the nonlinear wave evolution over variable bottom topographies. The model is extended with a solution to the rigid body that is tightly coupled to the hydrodynamic equations. The model was validated for two test cases that consider different floating structures of increasing geometrical complexity: a cylindrical geometry that is representative of a wave-energy-converter, and a vessel with a more complex shaped hull. A range of wave conditions were considered, varying from monochromatic to short-crested sea states. Model predictions of the excitation forces, added mass, radiation damping, and the wave-induced response agreed well with benchmark solutions to the potential flow equations. Besides the response to the primary wave (sea-swell) components, the model was also able to capture the second-order difference-frequency forcing and response of the moored vessel. Importantly, the model captured the wave-induced response with a relatively coarse vertical resolution, allowing for applications at the scale of a realistic harbour or coastal region. The proposed model thereby provides a new tool to seamlessly simulate the nonlinear evolution of waves over complex bottom topography and the wave-induced response of a floating structure that is moored in coastal waters.

Published
2022
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13. The impact of modulational instability on coastal wave forecasting using quadratic models

Author

Akrish, G. (author), Reniers, A.J.H.M. (author), Zijlema, Marcel (author), Smit, P.B. (author), Akrish, G. (author), Reniers, A.J.H.M. (author), Zijlema, Marcel (author), and Smit, P.B. (author)

Abstract

Coastal wave forecasting over large spatial scales is essential for many applications (e.g., coastal safety assessments, coastal management and developments, etc.). This demand explains the necessity for accurate yet effective models. A well-known efficient modelling approach is the quadratic approach (often referred to as frequency-domain models, nonlinear mild-slope models, amplitude models, etc.). The efficiency of this approach stems from a significant modelling reduction of the original governing equations (e.g., Euler equations). Most significantly, the description of wave nonlinearity essentially collapses into a single mode coupling term determined by the quadratic interaction coefficients. As a result, it is expected that the efficiency achieved by the quadratic approach is accompanied by a decrease in prediction accuracy. In order to gain further insight into the predictive capabilities of this modelling approach, this study examines six different quadratic formulations, three of which are of the Boussinesq type and the other three are referred to as fully dispersive. It is found that while the Boussinesq formulations reliably predict the evolution of coastal waves, the predictions by the fully dispersive formulations tend to be affected by false developments of modulational instability. Consequently, the predicted wave fields by the fully dispersive formulations are characterized by unexpectedly strong modulations of the sea-swell part and associated unexpected infragravity response. The impact of the modulational instability on wave prediction based on the quadratic approach is further demonstrated using existing laboratory results of bichromatic and irregular wave conditions., Environmental Fluid Mechanics

Published
2024
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14. QuadWave1D: An optimized quadratic formulation for spectral prediction of coastal waves

Author

Akrish, G. (author), Reniers, A.J.H.M. (author), Zijlema, Marcel (author), Smit, P.B. (author), Akrish, G. (author), Reniers, A.J.H.M. (author), Zijlema, Marcel (author), and Smit, P.B. (author)

Abstract

Spectral information of coastal waves and the associated statistical parameters (e.g., the significant wave height and mean wave period) over large spatial scales is essential for many applications (e.g., coastal safety assessments, coastal management and developments, etc.). This demand explains the necessity for accurate yet effective models. A well-known efficient modelling approach is the quadratic approach (often referred to as frequency-domain models, weakly nonlinear mild-slope models, amplitude models, etc.). The efficiency of this approach is achieved through modelling reduction of the original governing equations (e.g., Euler equations). Most significantly, wave nonlinearity is described solely by a single quadratic mode-coupling term. Therefore, doubts arise with regard to the predictive capabilities of the quadratic approach to reliably describe the nonlinear development of waves in the coastal environment where nonlinearity is typically significant. This study attempts to push the limit of the prediction capabilities of nonlinear coastal waves based on the quadratic approach. To this end, an optimization process is proposed, striving to extract the quadratic formulation which describes most adequately nonlinear wave developments over water depths and bathymetrical structures which characterize the coastal environment. The outcome is the model QuadWave1D: a fully dispersive quadratic model for coastal wave prediction in one-dimension. Based on a wide set of examples (including monochromatic, bichromatic and irregular wave conditions) and comparing to other representative quadratic formulations, it is found that QuadWave1D presents superior predictive capabilities of both the sea-swell components and the infragravity field., Environmental Fluid Mechanics

Published
2024
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23. Including the effect of depth-uniform ambient currents on waves in a non-hydrostatic wave-flow model

Author

Rijnsdorp, D.P. (author), van Rooijen, Arnold (author), Reniers, A.J.H.M. (author), Tissier, M.F.S. (author), de Wit, F.P. (author), Zijlema, Marcel (author), Rijnsdorp, D.P. (author), van Rooijen, Arnold (author), Reniers, A.J.H.M. (author), Tissier, M.F.S. (author), de Wit, F.P. (author), and Zijlema, Marcel (author)

Abstract

Currents can affect the evolution of waves in nearshore regions through altering their wavenumber and amplitude. Including the effect of ambient currents (e.g., tidal and wind-driven) on waves in phase-resolving wave models is not straightforward as it requires appropriate boundary conditions in combination with a large domain size and long simulation duration. In this paper, we extended the non-hydrostatic wave-flow model SWASH with additional terms that account for the influence of a depth-uniform ambient current on the wave dynamics, in which the current field can be taken from an external source (e.g., from observations or a circulation model). We verified the model ability by comparing predictions to results from linear theory, laboratory experiments and a spectral wave model that accounts for wave interference effects. With this extension, the model was able to account for current-induced changes to the wave field (i.e., changes to the wave amplitude, length and direction) due to following and opposing currents, and two classical examples of sheared currents (a jet-like current and vortex ring). Furthermore, the model captured the wave dynamics in the presence of strong opposing currents. This includes reflections of relatively small amplitude waves at the theoretical blocking point, and transmission of breaking waves beyond the theoretical blocking point for larger wave amplitudes. The proposed model extension allows phase-resolving models to more accurately and efficiently simulate the wave dynamics in coastal regions with tidal and/or wind-driven flows., Environmental Fluid Mechanics

Published
2023
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24. A mild-slope formulation based on Weyl rule of association with application to coastal wave modelling

Author

Akrish, G. (author), Smit, Pieter (author), Zijlema, Marcel (author), Reniers, A.J.H.M. (author), Akrish, G. (author), Smit, Pieter (author), Zijlema, Marcel (author), and Reniers, A.J.H.M. (author)

Abstract

Weyl rule of association, proposed by Hermann Weyl for quantum mechanics applications (Weyl, 1931), can be used to associate between the dispersion relation of water waves and a non-local pseudo-differential operator. The central result of this study is that this operator correctly approximates the Dirichlet-to-Neumann operator derived for linear waves over a slowly varying bathymetry. This opens the door to a formal use of Weyl's operational calculus, and consequently, allowing straightforward derivations and generalizations of water waves’ models over mild slopes. Specifically, within the framework of linear wave theory, the formulation based on Weyl rule of association provides a generalized mild-slope model which does not impose a limit on the spectral width. Most significantly, the mild-slope formulation based on Weyl rule of association allows to derive a general linear kinetic equation for which the widely used energy balance equation (the central equation of forecasting models such as SWAN and WAVEWATCH) serves as a special case. This result not only provides a formal link between the deterministic description (i.e., Euler equations) and the stochastic description (i.e., the energy balance equation), but also establishes the theoretical foundations for the statistical description of bathymetry-induced wave interferences. Such a statistical description is especially important over coastal waters, where through the interaction with the bathymetry, waves are rapidly scattered and tend to form focal zones and associated interference patterns., Environmental Fluid Mechanics

Published
2023
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25. Combining numerical tools to determine wave forces on moored ships

Author

Dobrochinski, João P.H. (author), van Deyzen, Alex (author), Zijlema, Marcel (author), van der Hout, A.J. (author), Dobrochinski, João P.H. (author), van Deyzen, Alex (author), Zijlema, Marcel (author), and van der Hout, A.J. (author)

Abstract

Accurate modelling of waves in harbours and the response of moored ships to that type of forcing is of prime importance to determine the safety and workability of ships moored at berths exposed to local wave conditions. This study investigates the combination of a non-hydrostatic wave-flow model (SWASH) and a 3D boundary-integral diffraction model (Harberth) to compute wave forces acting on moored ships. A series of systematic numerical tests has been performed to develop the proposed methodology and gain insight on its limits of application. The approach is validated using physical scale model test data of waves and forces acting on a restrained ship. Results indicate a good performance even for extremely energetic wave conditions, setting the investigated modelling approach as a potential alternative for future applications., Environmental Fluid Mechanics, Rivers, Ports, Waterways and Dredging Engineering

Published
2023
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30. Non-hydrostatic modelling of the wave-induced response of moored floating structures in coastal waters

Author

Rijnsdorp, D.P. (author), Wolgamot, Hugh (author), Zijlema, Marcel (author), Rijnsdorp, D.P. (author), Wolgamot, Hugh (author), and Zijlema, Marcel (author)

Abstract

Predictions of the wave-induced response of floating structures that are moored in a harbour or coastal waters require an accurate description of the (nonlinear) evolution of waves over variable bottom topography, the interactions of the waves with the structure, and the dynamics of the mooring system. In this paper, we present a new advanced numerical model to simulate the wave-induced response of a floating structure that is moored in an arbitrary nearshore region. The model is based on the non-hydrostatic approach, and implemented in the open-source model SWASH, which provides an efficient numerical framework to simulate the nonlinear wave evolution over variable bottom topographies. The model is extended with a solution to the rigid body equations (governing the motions of the floating structure) that is tightly coupled to the hydrodynamic equations (governing the water motion). The model was validated for two test cases that consider different floating structures of increasing geometrical complexity: a cylindrical geometry that is representative of a wave-energy-converter, and a vessel with a more complex shaped hull. A range of wave conditions were considered, varying from monochromatic to short-crested sea states. Model predictions of the excitation forces, added mass, radiation damping, and the wave-induced response agreed well with benchmark solutions to the potential flow equations. Besides the response to the primary wave (sea-swell) components, the model was also able to capture the second-order difference-frequency forcing and response of the moored vessel. Importantly, the model captured the wave-induced response with a relatively coarse vertical resolution, allowing for applications at the scale of a realistic harbour or coastal region. The proposed model thereby provides a new tool to seamlessly simulate the nonlinear evolution of waves over complex bottom topography and the wave-induced response of a floating structure that is moored in coastal w, Environmental Fluid Mechanics

Published
2022
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31. Corrigendum to “Non-hydrostatic modeling of drag, inertia and porous effects in wave propagation over dense vegetation fields”

Author

Suzuki, T. (author), Hu, Zhan (author), Kumada, Kenji (author), Phan Khanh, L. (author), Zijlema, Marcel (author), Suzuki, T. (author), Hu, Zhan (author), Kumada, Kenji (author), Phan Khanh, L. (author), and Zijlema, Marcel (author)

Abstract

The authors regret that there was a typo in Equation (14b)., Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., Environmental Fluid Mechanics, Coastal Engineering

Published
2022
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32. On the Efficiency of Staggered C-Grid Discretization for the Inviscid Shallow Water Equations from the Perspective of Nonstandard Calculus

Author

Zijlema, Marcel (author) and Zijlema, Marcel (author)

Abstract

This paper provides a rationale for the commonly observed numerical efficiency of staggered C-grid discretizations for solving the inviscid shallow water equations. In particular, using the key concepts of nonstandard calculus, we aim to show that the grid staggering of the primitive variables (surface elevation and normal velocity components) is capable of dealing with flow discontinuities. After a brief introduction of hyperreals through the notion of infinitesimal increments, a nonstandard rendition of the governing equations is derived that essentially turns into a finite procedure and permits a convenient way of modeling the hydraulic jumps in open channel flow. A central result of this paper is that the discrete formulations thus obtained are distinguished by the topological structures of the solution fields and subsequently provide a natural framework for the staggered discretization of the governing equations. Another key of the present study is to demonstrate that the discretization naturally regularizes the solution of the inviscid flow passing through the hydraulic jump without the need of non-physical dissipation. The underlying justification is provided by analytically studying the distributions of the flow variables across an infinitesimal thin hydraulic jump along with the use of hyperreal Heaviside step functions. This main finding is shown to be useful to comprehend the importance of the application of staggered finite difference schemes to accurately predict rapidly varying free-surface flows. A numerical experiment is provided to confirm this result., Environmental Fluid Mechanics

Published
2022
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33. SWAN SurfBeat-1D

Author

Reniers, A.J.H.M. (author), Zijlema, Marcel (author), Reniers, A.J.H.M. (author), and Zijlema, Marcel (author)

Abstract

The Simulating WAves Nearshore (SWAN) model has been extended with an infragravity module to predict the Wave-Group-Forced (WGF) infragravity response to a frequency-directional sea-swell spectrum at a mildly sloping alongshore uniform beach. To that end the SWAN model has been extended with an WGF-infragravity source term denoted Ssb where the subscript denotes surfbeat. The corresponding WGF infragravity energy model has been verified with a set of benchmark tests using the infragravity amplitude model of Reniers et al. (2002). Next the implementation of the energy balance in SWAN has been validated with both prototype-scale laboratory experiments and field observations, showing a good comparison with observations not affected by the nodal structure of the (partially) standing infragravity waves. This suggests that the model is capable of providing improved infragravity boundary conditions in relatively shallow water compared to the typical assumption of equilibrium forcing conditions using for instance Hasselmann's equilibrium theory (Hasselmann, 1962). These infragravity boundary conditions can subsequently can be used by other more sophisticated models to compute runup, overtopping and dune erosion., Environmental Fluid Mechanics

Published
2022
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38. Impacts of Tropical Cyclones on the Caribbean Under Future Climate Conditions

Author

Kleptsova, Olga S., Dijkstra, Henk A., van Westen, René M., van der Boog, Carine G., Katsman, Caroline A., James, Rebecca K., Bouma, Tjeerd J., Klees, Roland, Riva, Riccardo E. M., Slobbe, D. Cornelis, Zijlema, Marcel, Pietrzak, Julie D., Sub Physical Oceanography, Sub Dynamics Meteorology, Proceskunde, Sub AW Geofysica 2e geldstroom, Marine and Atmospheric Research, Sub Physical Oceanography, Sub Dynamics Meteorology, Proceskunde, Sub AW Geofysica 2e geldstroom, and Marine and Atmospheric Research

Subjects
Caribbean island, Ocean current, Climate change, Future climate, Oceanography, Atmosphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Caribbean region, Climatology, Taverne, Earth and Planetary Sciences (miscellaneous), Environmental science, Tropical cyclone, Coastal flood
Abstract

Joint effects of the dynamic sea-level rise projected changes in the large-scale atmosphere/ocean circulation, and wave climate on hurricane-induced extreme water levels in the Caribbean region are assessed. We use the 2D-depth integrated ADCIRC + SWAN wave-ocean model, baroclinically coupled to an ocean-eddying version of the Community Earth System Model, to compare impacts of the September 2017 hurricanes with projected impacts of similar hypothetical tropical storms occurring in the future. The model predicts only minor changes in the hurricane-induced extreme water levels for those Caribbean islands which were severely devastated by the 2017 tropical storms (Irma and Maria). That is, provided that the hurricane intensity remains at the present-day level, the global mean sea-level rise is the main future coastal flood risk factor.

Published
2021

41. Formulation of a Surf-Similarity Parameter to Predict Tsunami Characteristics at the Coast

Author

Roubos, Jochem J., Glasbergen, Toni, Hofland, Bas, Bricker, Jeremy D., Zijlema, Marcel, Esteban, Miguel, Tissier, Marion F. S., and TU Delft

Subjects
Wave Front Breaking, Tsunami, Wasserbau (627), Undular Bore, Küstenschutz/Küsteningenieurwesen (627.58), Surging, Continental Shelf, Bay Geometry, Surf-similarity Parameter
Abstract

To calculate tsunami forces on coastal structures it is of great importance to determine the shape of the tsunami front reaching the coast. Based on literature reviews, analytical reasoning, video footage, and numerical modelling it is concluded that both the continental shelf slope and the bay geometry have a significant influence on the transformation of a tsunami wave near the coastline. After conducting 1D and 2DH wave simulations, a distinction is made between three types of tsunami waves; a non-breaking front (surging), a breaking front and an undular bore breaking front. Tsunami waves transform into these three wave types over a steep continental shelf, an intermediate sloped continental shelf, and a gentle sloped continental shelf, respectively. A new tsunami surf-similarity parameter is proposed to quantitatively predict the type of wave at the coastline, which was validated based on observations during the 2011 Tohoku Earthquake and Tsunami., Journal of Coastal and Hydraulic Structures, Vol. 1 (2021)

Published
2021

42. Impacts of Tropical Cyclones on the Caribbean Under Future Climate Conditions

Author

Sub Physical Oceanography, Sub Dynamics Meteorology, Proceskunde, Sub AW Geofysica 2e geldstroom, Marine and Atmospheric Research, Kleptsova, Olga S., Dijkstra, Henk A., van Westen, René M., van der Boog, Carine G., Katsman, Caroline A., James, Rebecca K., Bouma, Tjeerd J., Klees, Roland, Riva, Riccardo E. M., Slobbe, D. Cornelis, Zijlema, Marcel, Pietrzak, Julie D., Sub Physical Oceanography, Sub Dynamics Meteorology, Proceskunde, Sub AW Geofysica 2e geldstroom, Marine and Atmospheric Research, Kleptsova, Olga S., Dijkstra, Henk A., van Westen, René M., van der Boog, Carine G., Katsman, Caroline A., James, Rebecca K., Bouma, Tjeerd J., Klees, Roland, Riva, Riccardo E. M., Slobbe, D. Cornelis, Zijlema, Marcel, and Pietrzak, Julie D.

Published
2021

43. Impacts of Tropical Cyclones on the Caribbean Under Future Climate Conditions

Author

Kleptsova, Olga S. (author), Dijkstra, Henk A. (author), van Westen, René M. (author), van der Boog, C.G. (author), Katsman, C.A. (author), James, Rebecca K. (author), Bouma, Tjeerd J. (author), Klees, R. (author), Riva, R.E.M. (author), Slobbe, D.C. (author), Zijlema, Marcel (author), Pietrzak, J.D. (author), Kleptsova, Olga S. (author), Dijkstra, Henk A. (author), van Westen, René M. (author), van der Boog, C.G. (author), Katsman, C.A. (author), James, Rebecca K. (author), Bouma, Tjeerd J. (author), Klees, R. (author), Riva, R.E.M. (author), Slobbe, D.C. (author), Zijlema, Marcel (author), and Pietrzak, J.D. (author)

Abstract

Joint effects of the dynamic sea-level rise projected changes in the large-scale atmosphere/ocean circulation, and wave climate on hurricane-induced extreme water levels in the Caribbean region are assessed. We use the 2D-depth integrated ADCIRC + SWAN wave-ocean model, baroclinically coupled to an ocean-eddying version of the Community Earth System Model, to compare impacts of the September 2017 hurricanes with projected impacts of similar hypothetical tropical storms occurring in the future. The model predicts only minor changes in the hurricane-induced extreme water levels for those Caribbean islands which were severely devastated by the 2017 tropical storms (Irma and Maria). That is, provided that the hurricane intensity remains at the present-day level, the global mean sea-level rise is the main future coastal flood risk factor., Hydraulic Engineering, Physical and Space Geodesy

Published
2021
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44. An efficient method to calculate depth-integrated, phase-averaged momentum balances in non-hydrostatic models

Author

da Silva, Renan F. (author), Rijnsdorp, D.P. (author), Hansen, Jeff E. (author), Lowe, Ryan (author), Buckley, Mark (author), Zijlema, Marcel (author), da Silva, Renan F. (author), Rijnsdorp, D.P. (author), Hansen, Jeff E. (author), Lowe, Ryan (author), Buckley, Mark (author), and Zijlema, Marcel (author)

Abstract

Analysis of the mean (wave-averaged) momentum balance is a common approach used to explain the physical forcing driving wave set-up and mean currents in the nearshore zone. Traditionally this approach has been applied to phase-averaged models but has more recently been applied to phase-resolving models using post-processing, whereby model output is used to calculate each of the momentum terms. While phase-resolving models have the advantage of capturing the nonlinear properties of waves propagating in the nearshore (making them advantageous to enhance understanding of nearshore processes), the post-processing calculation of the momentum terms does not guarantee that the momentum balance closes. We show that this is largely due to the difficulty (or impossibility) of being consistent with the numerical approach. If the residual is of a similar magnitude as any of the relevant momentum terms (which is common with post-processing methods as we show), the analysis is largely compromised. Here we present a new method to internally calculate and extract the depth-integrated, mean momentum terms in the phase-resolving non-hydrostatic wave-flow model SWASH in a manner that is consistent with the numerical implementation. Further, we demonstrate the utility of the new method with two existing physical model studies. By being consistent with the numerical framework, the internal method calculates the momentum terms with a much lower residual at computer precision, combined with greatly reduced calculation time and output storage requirements compared to post-processing techniques. The method developed here allows the accurate evaluation of the depth-integrated, mean momentum terms of wave-driven flows while taking advantage of the more complete representation of the wave dynamics offered by phase-resolving models. Furthermore, it provides an opportunity for advances in the understanding of nearshore processes particularly at more complex sites where wave nonlinearity and e, Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., Environmental Fluid Mechanics

Published
2021
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45. Formulation of a Surf-Similarity Parameter to Predict Tsunami Characteristics at the Coast

Author

Roubos, Jochem (author), Glasbergen, Toni (author), Hofland, Bas (author), Bricker, J.D. (author), Zijlema, Marcel (author), Esteban, Miguel (author), Tissier, M.F.S. (author), Roubos, Jochem (author), Glasbergen, Toni (author), Hofland, Bas (author), Bricker, J.D. (author), Zijlema, Marcel (author), Esteban, Miguel (author), and Tissier, M.F.S. (author)

Abstract

To calculate tsunami forces on coastal structures it is of great importance to determine the shape of the tsunami front reaching the coast. Based on literature reviews, analytical reasoning,video footage, and numerical modelling it is concluded that both the continental shelf slope and the bay geometry have a significant influence on the transformation of a tsunami wave near the coastline. After conducting 1D and 2DH wave simulations, a distinction is made between three types of tsunami waves; a non-breaking front (surging), a breaking front and an undular bore breaking front. Tsunami waves transform into these three wave types over a steep continental shelf, an intermediate sloped continental shelf, and a gentle sloped continental shelf, respectively. A new tsunami surf-similarityparameter is proposed to quantitatively predict the type of wave at the coastline, which was validated based on observations during the 2011 Tohoku Earthquake and Tsunami., Hydraulic Structures and Flood Risk, Environmental Fluid Mechanics

Published
2021
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46. Free Infragravity Waves in the North Sea

Author

Rijnsdorp, D.P. (author), Reniers, A.J.H.M. (author), Zijlema, Marcel (author), Rijnsdorp, D.P. (author), Reniers, A.J.H.M. (author), and Zijlema, Marcel (author)

Abstract

Infragravity waves are low-frequency surface waves that can impact a variety of nearshore and oceanic processes. Recent measurements in the North Sea showed that significant bursts of infragravity energy occurred during storm events. Using a spectral wave model, we show that a substantial part of this energy was radiated from distant shorelines where it was generated by the incident sea-swell waves. These radiated infragravity waves can cross the North Sea basin and reach distant shorelines. The origin of the infragravity wave energy varied between the different storms, and particularly depends on where largest sea-swell waves made landfall. Along the coastlines of the North Sea, shoreward directed infragravity waves that originate from a remote source were non-negligible during storm events. This suggests that radiated infragravity waves can potentially contribute to coastal dynamics and hazards away from their region of generation., Environmental Fluid Mechanics

Published
2021
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47. On the accuracy of internal wave generation method in a non-hydrostatic wave model to generate and absorb dispersive and directional waves

Author

Vasarmidis, Panagiotis (author), Stratigaki, Vasiliki (author), Suzuki, T. (author), Zijlema, Marcel (author), Troch, Peter (author), Vasarmidis, Panagiotis (author), Stratigaki, Vasiliki (author), Suzuki, T. (author), Zijlema, Marcel (author), and Troch, Peter (author)

Abstract

The weakly reflective wave generation is a wave generation and absorption method in phase-resolving models, based on the assumption that the waves propagating towards the wave generation boundary are small amplitude shallow water waves with direction perpendicular to the boundary. This assumption makes the method weakly reflective for dispersive and directional waves. The internal wave generation method was proposed by Vasarmidis et al. (2019b) as an alternative, for the non-hydrostatic wave model, SWASH, to avoid reflections. In this study, a comparison is made between the performance of the new internal wave generation method and the weakly reflective wave generation method. It is shown that using the internal wave generation leads to a significantly more accurate prediction of the resulting wave field in case of waves reflected back to the numerical boundary. Additionally, the internal wave generation method is extended to short-crested waves and SWASH is validated for the first time with experimental data for the cases of wave propagation over a shoal and wave diffraction around a wall. The proposed extended internal wave generation method increases the capability of SWASH towards the study of wave propagation of highly dispersive short-crested waves in coastal environments with minimal reflection from the boundaries., Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., Environmental Fluid Mechanics

Published
2021
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48. Physics-Capturing Discretizations for Spectral Wind-Wave Models

Author

Zijlema, Marcel (author) and Zijlema, Marcel (author)

Abstract

This paper discusses the discretization methods that have been commonly employed to solve the wave action balance equation, and that have gained a renewed interest with the widespread use of unstructured grids for third-generation spectral wind-wave models. These methods are the first-order upwind finite difference and first-order vertex-centered upwind finite volume schemes for the transport of wave action in geographical space. The discussion addresses the derivation of these schemes from a different perspective. A mathematical framework for mimetic discretizations based on discrete calculus is utilized herein. A key feature of this algebraic approach is that the process of exact discretization is segregated from the process of interpolation, the latter typically involved in constitutive relations. This can help gain insight into the performance characteristics of the discretization method. On this basis, we conclude that the upwind finite difference scheme captures the wave action flux conservation exactly, which is a plus for wave shoaling. In addition, we provide a justification for the intrinsic low accuracy of the vertex-centred upwind finite volume scheme, due to the physically inaccurate but common flux constitutive relation, and we propose an improvement to overcome this drawback. Finally, by way of a comparative demonstration, a few test cases is introduced to establish the ability of the considered methods to capture the relevant physics on unstructured triangular meshes., Environmental Fluid Mechanics

Published
2021
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50. Ocean model resolution dependence of Caribbean sea-level projections

Author

Coastal dynamics, Fluvial systems and Global change, Sub Physical Oceanography, Sub Dynamics Meteorology, Proceskunde, van Westen, René M., Dijkstra, Henk A., van der Boog, Carine G., Katsman, Caroline A., James, Rebecca K., Bouma, Tjeerd J., Kleptsova, Olga, Klees, Roland, Riva, Riccardo E.M., Slobbe, D. Cornelis, Zijlema, Marcel, Pietrzak, Julie D., Coastal dynamics, Fluvial systems and Global change, Sub Physical Oceanography, Sub Dynamics Meteorology, Proceskunde, van Westen, René M., Dijkstra, Henk A., van der Boog, Carine G., Katsman, Caroline A., James, Rebecca K., Bouma, Tjeerd J., Kleptsova, Olga, Klees, Roland, Riva, Riccardo E.M., Slobbe, D. Cornelis, Zijlema, Marcel, and Pietrzak, Julie D.

Published
2020

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