Efficient two-layer non-hydrostatic wave model with accurate dispersive behaviour

Ridder, Menno P. de; Smit, Pieter; Dongeren, Ap van; McCall, Robert; Nederhoff, Kees; Reniers, Ad

doi:10.1016/j.coastaleng.2020.103808

Cited by 25 publications

(17 citation statements)

References 45 publications

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“…The empirical relations presented in this paper were derived from many 1D XBeach-NH+ model runs [18], in which a wide range of offshore boundary conditions and crossshore geometries were simulated. Time series of vertical run-up were extracted from the results, and from these the mean set-up (z mean ), and the incident (S inc ) and infragravity (S IG ) components were computed.…”

Section: Methodsmentioning

confidence: 99%

“…The profile in the surf zone is schematized with a Dean profile [20] up to a depth of 4 times the offshore wave height. Beyond the surf zone, the bathymetry gradually drops to a depth where n (C/C g ) equals 0.8 [18]. The cross-shore grid resolution varies along the profile, such that individual waves are covered by approximately 80 grid cells.…”

Section: Model Set-upmentioning

confidence: 99%

“…Vertical run-up time series z t were obtained from a run-up gauge in the model which tracks the most landward wet point. The threshold water depth for determining whether a grid cell is wet was set to 0.01 m. Tests with this parameter did not show strong sensitivity to the results in the range between 0.01 and 0.05 m. The maximum breaker steepness was set to 0.6, as recommended by [18].…”

Section: Model Set-upmentioning

confidence: 99%

“…In the present approach study, we apply the XBeach-NH+ model [18] which is a quasi-two-layer dispersive model which resolves both the incident and infragravity waves up to a relative depth kh of 4. This model has shown good skill in predicting the wave hydrodynamics in field conditions [6] and wave run-up in laboratory conditions [7].…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

A Model-Derived Empirical Formulation for Wave Run-Up on Naturally Sloping Beaches

Ormondt

Roelvink

Dongeren

2021

JMSE

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A new set of empirical formulations has been derived to predict wave run-up at naturally sloping sandy beaches. They are obtained by fitting the results of hundreds of XBeach-NH+ model simulations. The simulations are carried out over a wide range of offshore wave conditions (wave heights ranging from 1 to 12 m and periods from 6 to 16 s), and surf zone (Dean parameters aD ranging from 0.05 to 0.30) and beach geometries (slopes ranging from 1:100 to 1:5). The empirical formulations provide estimates of wave set-up, incident and infragravity wave run-up, and total run-up R2%. Reduction coefficients are included to account for the effects of incident wave angle and directional spreading. The formulations have been validated against the Stockdon dataset and show better skill at predicting R2% run-up than the widely used Stockdon relationships. Unlike most existing run-up predictors, the relations presented here include the effect of the surf zone slope, which is shown to be an important parameter for predicting wave run-up. Additionally, this study shows a clear relationship between infragravity run-up and beach slope, unlike most existing predictors.

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Section: Methodsmentioning

confidence: 99%

Section: Model Set-upmentioning

confidence: 99%

Section: Model Set-upmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Model-Derived Empirical Formulation for Wave Run-Up on Naturally Sloping Beaches

Ormondt

Roelvink

Dongeren

2021

JMSE

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“…Wave-resolving models. One solution to the difficulty in parameterizing wave behavior in shallow water is to resort to wave-resolving models such as MITgcm, TRIM, SUNTANS, SWASH, CROCO, NHWAVE, FUNWAVE, Celeris, and XBeach-NH+ (Marshall et al 1997, Casulli 1999, Fringer et al 2006, Zijlema et al 2011, Debreu et al 2012, Ma et al 2014, Malej et al 2015, Tavakkol & Lynett 2017, and de Ridder et al 2021, which are capable of skillfully simulating the shapes and orbital motions of nonlinear waves (e.g., Tissier et al 2011, Smit et al 2014) and, critically, can resolve water-level variations associated with setup and swash. Although most wave-resolving models lack sediment-transport formulations and are still too computationally expensive to simulate regional-scale nearshore morphodynamics, we anticipate that this will change, and that wave-resolving models will be improved to incorporate breaking-induced turbulence, be coupled with sediment-transport formulae (e.g., van der A et al 2013van der A et al , Fringer et al 2019, and become more common components of coastal morphodynamic models.…”

Section: Processesmentioning

confidence: 99%

Modeling the Morphodynamics of Coastal Responses to Extreme Events: What Shape Are We In?

Sherwood

Dongeren

Doyle

et al. 2022

Annu. Rev. Mar. Sci.

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This review focuses on recent advances in process-based numerical models of the impact of extreme storms on sandy coasts. Driven by larger-scale models of meteorology and hydrodynamics, these models simulate morphodynamics across the Sallenger storm-impact scale, including swash, collision, overwash, and inundation. Models are becoming both wider (as more processes are added) and deeper (as detailed physics replaces earlier parameterizations). Algorithms for wave-induced flows and sediment transport under shoaling waves are among the recent developments. Community and open-source models have become the norm. Observations of initial conditions (topography, land cover, and sediment characteristics) have become more detailed, and improvements in tropical cyclone and wave models provide forcing (winds, waves, surge, and upland flow) that is better resolved and more accurate, yielding commensurate improvements in model skill. We foresee that future storm-impact models will increasingly resolve individual waves, apply data assimilation, and be used in ensemble modeling modes to predict uncertainties. Expected final online publication date for the Annual Review of Marine Science, Volume 14 is January 2022. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Water Level Modulation of Wave Transformation, Setup and Runup over La Saline Fringing Reef

Bruch

Cordier

Floc'H

et al. 2022

Preprint

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Low-latitude and often low-lying islands are frequently located in oceanic regions prone to extreme natural events and disasters of hydro-meteorological origin, such as tropical cyclones, storms, flooding, and drought. In the context of global climate change, growing concern for the future of these environments has resulted in recent initiatives (e.g., UNESCO, 2014) for the building of small island resilience. Many of these tropical environments are bordered by coral reefs that are home to some of the most biodiverse and productive ecosystems on the planet (Pascal et al., 2016;Woodhead et al., 2019) and provide extremely valuable ecosystem services as a coastal defense against these events. An increasing number of studies indicate that up to 98% of incident wave energy is dissipated by coral reef systems (

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Efficient two-layer non-hydrostatic wave model with accurate dispersive behaviour

Cited by 25 publications

References 45 publications

A Model-Derived Empirical Formulation for Wave Run-Up on Naturally Sloping Beaches

A Model-Derived Empirical Formulation for Wave Run-Up on Naturally Sloping Beaches

Modeling the Morphodynamics of Coastal Responses to Extreme Events: What Shape Are We In?

Water Level Modulation of Wave Transformation, Setup and Runup over La Saline Fringing Reef

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