Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Modeling depth-induced wave breaking over complex coastal bathymetries
https://orcid.org/0000-0003-0154-5005
Abstract The correct representation of depth-induced wave breaking is important for understanding coastal morphology and for design and management in the coastal zone. Although numerous studies have demonstrated the applicability of a constant scaling of the Battjes and Janssen (1978) dissipation model for depth-induced breaking, recent studies have shown its inability to sufficiently reproduce wave dissipation over complex field cases. In the present study, we contrast the application of such a constant scaling to two alternative wave breaking parameterizations with a variable scaling based on either the wave nonlinearity (the φ parameterization) or on both bottom slope and normalized wavelength supplemented with wave directionality (the β−kd parameterization). We consider three field data sets characteristic of a simple beach-bar profile, a bay partially protected by a shoal and a complex intertidal region. We demonstrate that in these cases the β−kd parameterization provides a better alternative to the use of a constant scaling or the φ parameterization. To illustrate the operational consequences, we up-scale the conditions over the case of the intertidal region to correspond to design conditions for the Dutch coast (storm conditions with a 4000year return period). Under these extreme conditions, for locally generated waves both the β−kd and φ parameterizations predict qualitatively similar increased significant wave heights but the β−kd parameterization increased the waves twice as much as the φ parameterization. Under other conditions, when non-locally generated waves (swell) dissipates over a gently sloping bottom, the β−kd parameterization predicts lower significant wave heights compared to either the constant scaling or φ parameterization.
Highlights Two variable scalings for wave breaking models are compared to a constant scaling. Both alternatives show improved wave height predictions of locally generated waves. Both alternatives enhance the significant wave height of locally generated waves. The β−kd scaling also improves non-locally generated wave heights over gentle slopes. Differences in the predicted wave-induced forces are shown in an upscaled storm.
Modeling depth-induced wave breaking over complex coastal bathymetries
https://orcid.org/0000-0003-0154-5005
Abstract The correct representation of depth-induced wave breaking is important for understanding coastal morphology and for design and management in the coastal zone. Although numerous studies have demonstrated the applicability of a constant scaling of the Battjes and Janssen (1978) dissipation model for depth-induced breaking, recent studies have shown its inability to sufficiently reproduce wave dissipation over complex field cases. In the present study, we contrast the application of such a constant scaling to two alternative wave breaking parameterizations with a variable scaling based on either the wave nonlinearity (the φ parameterization) or on both bottom slope and normalized wavelength supplemented with wave directionality (the β−kd parameterization). We consider three field data sets characteristic of a simple beach-bar profile, a bay partially protected by a shoal and a complex intertidal region. We demonstrate that in these cases the β−kd parameterization provides a better alternative to the use of a constant scaling or the φ parameterization. To illustrate the operational consequences, we up-scale the conditions over the case of the intertidal region to correspond to design conditions for the Dutch coast (storm conditions with a 4000year return period). Under these extreme conditions, for locally generated waves both the β−kd and φ parameterizations predict qualitatively similar increased significant wave heights but the β−kd parameterization increased the waves twice as much as the φ parameterization. Under other conditions, when non-locally generated waves (swell) dissipates over a gently sloping bottom, the β−kd parameterization predicts lower significant wave heights compared to either the constant scaling or φ parameterization.
Highlights Two variable scalings for wave breaking models are compared to a constant scaling. Both alternatives show improved wave height predictions of locally generated waves. Both alternatives enhance the significant wave height of locally generated waves. The β−kd scaling also improves non-locally generated wave heights over gentle slopes. Differences in the predicted wave-induced forces are shown in an upscaled storm.
Modeling depth-induced wave breaking over complex coastal bathymetries
https://orcid.org/0000-0003-0154-5005
Abstract The correct representation of depth-induced wave breaking is important for understanding coastal morphology and for design and management in the coastal zone. Although numerous studies have demonstrated the applicability of a constant scaling of the Battjes and Janssen (1978) dissipation model for depth-induced breaking, recent studies have shown its inability to sufficiently reproduce wave dissipation over complex field cases. In the present study, we contrast the application of such a constant scaling to two alternative wave breaking parameterizations with a variable scaling based on either the wave nonlinearity (the φ parameterization) or on both bottom slope and normalized wavelength supplemented with wave directionality (the β−kd parameterization). We consider three field data sets characteristic of a simple beach-bar profile, a bay partially protected by a shoal and a complex intertidal region. We demonstrate that in these cases the β−kd parameterization provides a better alternative to the use of a constant scaling or the φ parameterization. To illustrate the operational consequences, we up-scale the conditions over the case of the intertidal region to correspond to design conditions for the Dutch coast (storm conditions with a 4000year return period). Under these extreme conditions, for locally generated waves both the β−kd and φ parameterizations predict qualitatively similar increased significant wave heights but the β−kd parameterization increased the waves twice as much as the φ parameterization. Under other conditions, when non-locally generated waves (swell) dissipates over a gently sloping bottom, the β−kd parameterization predicts lower significant wave heights compared to either the constant scaling or φ parameterization.
Highlights Two variable scalings for wave breaking models are compared to a constant scaling. Both alternatives show improved wave height predictions of locally generated waves. Both alternatives enhance the significant wave height of locally generated waves. The β−kd scaling also improves non-locally generated wave heights over gentle slopes. Differences in the predicted wave-induced forces are shown in an upscaled storm.
Modeling depth-induced wave breaking over complex coastal bathymetries
Salmon, J.E. (Autor:in) / Holthuijsen, L.H. (Autor:in)
Coastal Engineering ; 105 ; 21-35
06.08.2015
15 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Modeling depth-induced wave breaking over complex coastal bathymetries
| British Library Online Contents | 2015
Modeling depth-induced wave breaking over complex coastal bathymetries
| British Library Online Contents | 2015
Simulation of wave breaking over complex bathymetries by a Boussinesq model
| Online Contents | 2011
Evaluation of the PG method for modeling unsteady flows in complex bathymetries
| Taylor & Francis Verlag | 2018