%0 Journal Article %1 Arriaga20201 %A Arriaga, J. %A Ribas, F. %A Falqués, A. %A Rutten, J. %A Ruessink, G. %D 2020 %I MDPI AG %J Journal of Marine Science and Engineering %K 2020 AlongshoreTransport HighAngleWaveInstability MegaNourishment MorphodynamicModeling ShorelineDiffusivity from:erick007 %N 12 %P 1-21 %R 10.3390/jmse8120965 %T Long-term performance of mega-nourishments: Role of directional wave climate and initial geometry %U https://www.scopus.com/inward/record.uri?eid=2-s2.0-85097274360&doi=10.3390%2fjmse8120965&partnerID=40&md5=9faeb0aec1eaa8e56d0fdc5b49a49158 %V 8 %X Concentrated mega-nourishments, built as coastal protection measures for decadal time scales, are intended to diffuse, that is to erode and to supply sand to the nearby beaches and dunes by profiting of the natural drivers. Here, we aim to quantify the role of the wave incidence angle and initial geometry on the long-term evolution of mega-nourishments, in particular the Zandmotor (the Netherlands), using a nonlinear morphodynamic model for large-scale shoreline dynamics. Synthetic wave climates based on measurements are created to systematically vary the wave conditions. Simulations show that mega-nourishment diffusivity decreases linearly with an increasing percentage of high-angle waves (>45◦ incidence with respect to the global shoreline orientation in deep water). For wave climates with more than 80% of high-angle waves, erosional hotspots develop at the sides of the mega-nourishment. In unimodal high-angle wave climates, hotspot growth rates are large and alongshore migration of the nourishment can increase up to 40 m/year. The role of initial geometry is studied by creating synthetic nourishments that vary in shape, asymmetry, and volume. Slender initial shapes are less diffusive than wider shapes. The initial asymmetry influences the asymmetry in sand feeding to adjacent beaches throughout 50 years, which for symmetric nourishments is controlled by the imbalance in the wave climate. Smaller nourishments than the Zandmotor are more diffusive. This work contributes to a more general understanding of mega-nourishment evolution and may serve as guide for future mega-nourishment design. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.

@article{Arriaga20201, abbrev_source_title = {J. Mar. Sci. Eng.}, abstract = {Concentrated mega-nourishments, built as coastal protection measures for decadal time scales, are intended to diffuse, that is to erode and to supply sand to the nearby beaches and dunes by profiting of the natural drivers. Here, we aim to quantify the role of the wave incidence angle and initial geometry on the long-term evolution of mega-nourishments, in particular the Zandmotor (the Netherlands), using a nonlinear morphodynamic model for large-scale shoreline dynamics. Synthetic wave climates based on measurements are created to systematically vary the wave conditions. Simulations show that mega-nourishment diffusivity decreases linearly with an increasing percentage of high-angle waves (>45◦ incidence with respect to the global shoreline orientation in deep water). For wave climates with more than 80% of high-angle waves, erosional hotspots develop at the sides of the mega-nourishment. In unimodal high-angle wave climates, hotspot growth rates are large and alongshore migration of the nourishment can increase up to 40 m/year. The role of initial geometry is studied by creating synthetic nourishments that vary in shape, asymmetry, and volume. Slender initial shapes are less diffusive than wider shapes. The initial asymmetry influences the asymmetry in sand feeding to adjacent beaches throughout 50 years, which for symmetric nourishments is controlled by the imbalance in the wave climate. Smaller nourishments than the Zandmotor are more diffusive. This work contributes to a more general understanding of mega-nourishment evolution and may serve as guide for future mega-nourishment design. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.}, added-at = {2021-05-28T02:15:43.000+0200}, affiliation = {Cátedras-CONACyT, Consejo Nacional de Ciencia y Tecnología, Insurgentes Sur 1582, Ciudad de México, 03940, Mexico; Laboratorio de Ingeniería y Procesos Costeros, Universidad Nacional Autónoma de México (UNAM), Puerto de Abrigo, Sisal, 97355, Mexico; Laboratorio Nacional de Resiliencia Costera, Laboratorios Nacionales CONACYTYucatán 97835, Mexico; Physics Department, Universitat Politècnica de Catalunya (UPC), Jordi Girona 1-3, Barcelona, 08034, Spain; Department of Physical Geography, Faculty of Geosciences, Utrecht University, Princetonlaan 8a, Utrecht, 3584 CS, Netherlands}, art_number = {965}, author = {Arriaga, J. and Ribas, F. and Falqués, A. and Rutten, J. and Ruessink, G.}, biburl = {https://www.bibsonomy.org/bibtex/249c585ba6efe64ac9f98d18685837abe/publ_del_lipc}, correspondence_address1 = {Arriaga, J.; Cátedras-CONACyT, Insurgentes Sur 1582, Mexico; email: jarriagag@iingen.unam.mx; Arriaga, J.; Laboratorio de Ingeniería y Procesos Costeros, Puerto de Abrigo, Mexico; email: jarriagag@iingen.unam.mx; Arriaga, J.; Laboratorio Nacional de Resiliencia Costera, Mexico; email: jarriagag@iingen.unam.mx}, document_type = {Article}, doi = {10.3390/jmse8120965}, funding_details = {CB 2016/284430}, funding_text 1 = {Funding: This research was partly funded by the Spanish Government projects CTM2015-66225-C2-1-P and RTI2018-093941-B-C33 (MCIU/AEI/FEDER). The first author is funded by the Catedras CONACYT project 1146 and received support from the project PAPIIT IN101218 (DGAPA-UNAM). Jantien Rutten is funded through CONACYT Project CB 2016/284430. Gerben Ruessink acknowledges funding by the Dutch Technology Foundation STW, which is part of the Dutch Organisation for Scientific Research (NWO) and is partly funded by the Ministry of Economic Affairs, under contract 12686 (NatureCoast).}, interhash = {70fd6c48d0cf6f9eb53e53b8a108bce3}, intrahash = {49c585ba6efe64ac9f98d18685837abe}, issn = {20771312}, journal = {Journal of Marine Science and Engineering}, keywords = {2020 AlongshoreTransport HighAngleWaveInstability MegaNourishment MorphodynamicModeling ShorelineDiffusivity from:erick007}, language = {English}, number = 12, pages = {1-21}, publisher = {MDPI AG}, source = {Scopus}, timestamp = {2021-06-23T06:13:18.000+0200}, title = {Long-term performance of mega-nourishments: Role of directional wave climate and initial geometry}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85097274360&doi=10.3390%2fjmse8120965&partnerID=40&md5=9faeb0aec1eaa8e56d0fdc5b49a49158}, volume = 8, year = 2020 }