Print Email Facebook Twitter SWAN SurfBeat-1D Title SWAN SurfBeat-1D Author Reniers, A.J.H.M. (TU Delft Environmental Fluid Mechanics) Zijlema, Marcel (TU Delft Environmental Fluid Mechanics) Date 2022 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. Subject Bound and free infragravity wavesField and laboratory validationSpectral modeling To reference this document use: http://resolver.tudelft.nl/uuid:219cdb99-e105-48a1-92b9-dda7d4c2ac31 DOI https://doi.org/10.1016/j.coastaleng.2021.104068 ISSN 0378-3839 Source Coastal Engineering, 172 Part of collection Institutional Repository Document type journal article Rights © 2022 A.J.H.M. Reniers, Marcel Zijlema Files PDF 1_s2.0_S0378383921002040_main.pdf 2.92 MB Close viewer /islandora/object/uuid:219cdb99-e105-48a1-92b9-dda7d4c2ac31/datastream/OBJ/view