Fully Nonlinear Potential Flow Simulations of Wave Shoaling Over Slopes: Spilling Breaker Model and Integral Wave Properties

Grilli, Stéphan T.; Horrillo, Juan; Guignard, Stephan

doi:10.1007/s42286-019-00017-6

Cited by 17 publications

(28 citation statements)

References 93 publications

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“…Grilli et al (1997) showed that the model could accurately predict breaking crest elevations, breaker index, and breaker types for solitary waves of various incident height propagating over mild to steep slopes. Finally, Grilli et al (2019) show that the model also accurately simulates the shoaling and propagation of periodic waves over a bar similar to that considered here. B9-r 97.2 1.43 0.7 2 10 0.57 0.08 0 0 Blenkinsopp and Chaplin (2007) Note.…”

Section: Appendix A: Sensitivity Of Local Geometric Parameters Used Imentioning

confidence: 53%

A Unified Breaking Onset Criterion for Surface Gravity Water Waves in Arbitrary Depth

et al. 2020

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We investigate the validity and robustness of the Barthelemy et al. (2018, https://doi.org/10.1017/jfm.2018.93) wave‐breaking onset prediction framework for surface gravity water waves in arbitrary water depth, including shallow water breaking over varying bathymetry. We show that the Barthelemy et al. (2018) breaking onset criterion, which they validated for deep and intermediate water depths, also segregates breaking crests from nonbreaking crests in shallow water, with subsequent breaking always following the exceedance of their proposed generic breaking threshold. We consider a number of representative wave types, including regular, irregular, solitary, and focused waves, shoaling over idealized bed topographies including an idealized bar geometry and a mildly to steeply sloping planar beach. Our results show that the new breaking onset criterion is capable of detecting single and multiple breaking events in time and space in arbitrary water depth. Further, we show that the new generic criterion provides improved skill for signaling imminent breaking onset, relative to the available kinematic or geometric breaking onset criteria in the literature. In particular, the new criterion is suitable for use in wave‐resolving models that cannot intrinsically detect the onset of wave breaking.

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Section: Appendix A: Sensitivity Of Local Geometric Parameters Used Imentioning

confidence: 53%

A Unified Breaking Onset Criterion for Surface Gravity Water Waves in Arbitrary Depth

et al. 2020

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“…The implementation and validation of wave breaking dissipation methods have been presented for the fully nonlinear potential flow solver whispers3D in the case of two dimensional waves. Among the various breaking models presented in the literature, three existing dissipation methods were implemented here: HJ and HJf, based on the analogy between a breaking wave and a hydraulic jump (Guignard and Grilli, 2001;Grilli et al, 2019), and an eddy viscosity-like formulation of the dissipation (Kennedy et al, 2000). Three initiation criteria for wave breaking were also compared.…”

Section: Resultsmentioning

confidence: 99%

“…(3). The first method (denoted HJ in the following) uses an analogy with a hydraulic jump propagating over a flat bottom to estimate a pressure term D = −P surf /ρ, with ρ the water density (Guignard and Grilli, 2001;Grilli et al, 2019). The zone where the pressure is applied extends on both sides of the breaking wave crest between x f and x b (see Figure 1…”

Section: Wave Energy Dissipation Mechanismsmentioning

confidence: 99%

“…Following the detection of the onset of wave breaking, several different dissipation mechanisms can be applied by adding a term to the dynamic free surface boundary condition. Over the specified spatial extent of wave breaking, the wave energy dissipation can be calculated using a surface roller model (Schäffer et al, 1993), a vorticity model (Svendsen et al, 1978), an eddy viscosity model (Kennedy et al, 2000;Kurnia and van Groesen, 2014;Papoutsellis et al, 2018bPapoutsellis et al, , 2019, or by analogy with a hydraulic jump (Guignard and Grilli, 2001;Grilli et al, 2019;Papoutsellis et al, 2019). These mechanisms require parameterizing both the definition of the onset of wave breaking and the intensity and spatial extent of the applied dissipation.…”

Section: Introductionmentioning

confidence: 99%

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Comparing methods of modeling depth-induced breaking of irregular waves with a fully nonlinear potential flow approach

Simon

Papoutsellis

Benoît

et al. 2019

J. Ocean Eng. Mar. Energy

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The modeling of wave breaking dissipation in coastal areas is investigated with a fully nonlinear and dispersive wave model. The wave propagation model is based on potential flow theory, which initially assumes nonoverturning waves. Including the impacts of wave breaking dissipation is however possible by implementing a wave breaking initiation criterion and dissipation mechanism. Three criteria from the literature, including a geometric, kinematic, and dynamic-type criterion, are tested to determine the optimal criterion predicting the onset of wave breaking. Three wave breaking energy dissipation methods are also tested: the first two are based on the analogy of a breaking wave with a hydraulic jump, and the third one applies an eddy viscosity dissipative term. Numerical simulations are performed using combinations of the three breaking onset criteria and three dissipation methods. The simulation results are compared to observations from four laboratory experiments of regular and irregular waves breaking over a submerged bar, irregular waves breaking on a beach, and irregular waves breaking over a submerged slope. The different breaking approaches provide similar results after proper calibration. The wave transformation observed in the experiments is reproduced well, with better results for the case of regular waves than irregular waves. Moreover, the wave statistics and wave spectra are predicted well in general, and in particular for regular waves. Some differences are observed for irregular wave cases, in particular in the low-frequency range. This is attributed to incomplete absorption of the long waves in the numerical model. Otherwise, the wave spectra in the range [0.5fp, 5fp] are reproduced well, before, inside, and after the breaking zone for the three irregular wave experiments.

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“…The term introduced in the FSBC is computed by solving a differential equation derived by requiring that momentum is conserved as the waves break over a flat bottom. The second method, EHJ, is the implementation of the dissipative term proposed by Guignard and Grilli (2001) and Grilli et al (2019). This term is constructed such that it produces negative work proportional to the work done by a hydraulic jump with wave characteristics similar to those of the breaking wave.…”

Section: Discussionmentioning

confidence: 99%

Modelling of depth-induced wave breaking in a fully nonlinear free-surface potential flow model

Papoutsellis

Yates

Simon

et al. 2019

Coastal Engineering

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Two methods to treat wave breaking in the framework of the Hamiltonian formulation of free-surface potential flow are presented, tested, and validated. The first is an extension of Kennedy et al. (2000)'s eddyviscosity approach originally developed for Boussinesq-type wave models. In this approach, an extra term, constructed to conserve the horizontal momentum for waves propagating over a flat bottom, is added in the dynamic free-surface condition. In the second method, a pressure distribution is introduced at the free surface that dissipates wave energy by analogy to a hydraulic jump (Guignard and Grilli, 2001). The modified Hamiltonian systems are implemented using the Hamiltonian Coupled-Mode Theory, in which the velocity potential is represented by a rapidly convergent vertical series expansion. Wave energy dissipation and conservation of horizontal momentum are verified numerically. Comparisons with experimental measurements are presented for the propagation of a breaking dispersive shock wave following a dam break, and then incident regular waves breaking on a mildly sloping beach and over a submerged bar.Keywords: wave breaking, Hamiltonian formulation of water waves, eddyviscosity, fully nonlinear water waves Highlights• Two wave breaking techniques are tested in a fully nonlinear model. • Breaking is implemented by extending the Hamiltonian Coupled-Mode

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Fully Nonlinear Potential Flow Simulations of Wave Shoaling Over Slopes: Spilling Breaker Model and Integral Wave Properties

Cited by 17 publications

References 93 publications

A Unified Breaking Onset Criterion for Surface Gravity Water Waves in Arbitrary Depth

A Unified Breaking Onset Criterion for Surface Gravity Water Waves in Arbitrary Depth

Comparing methods of modeling depth-induced breaking of irregular waves with a fully nonlinear potential flow approach

Modelling of depth-induced wave breaking in a fully nonlinear free-surface potential flow model

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