TY - JOUR
T1 - A Clustering Approach for Predicting Dune Morphodynamic Response to Storms Using Typological Coastal Profiles
T2 - A Case Study at the Dutch Coast
AU - Athanasiou, Panagiotis
AU - van Dongeren, Ap
AU - Giardino, Alessio
AU - Vousdoukas, Michalis
AU - Antolinez, Jose A.A.
AU - Ranasinghe, Roshanka
N1 - Funding Information:
This work has received funding from the EU Horizon 2020 Program for Research and Innovation, under grant agreement no 776613 (EUCP: “European Climate Prediction system;” https: //www.eucp-project.eu). AD was funded in part by the Deltares Strategic Research Programme “Natural Hazards”, while AG from the Research Programme “Seas and Coastal Zones”. RR is supported by the AXA Research fund and partly supported by the Deltares Research program “Seas and Coastal Zones”.
Publisher Copyright:
© Copyright © 2021 Athanasiou, van Dongeren, Giardino, Vousdoukas, Antolinez and Ranasinghe.
PY - 2021/9/23
Y1 - 2021/9/23
N2 - Dune erosion driven by extreme marine storms can damage local infrastructure or ecosystems and affect the long-term flood safety of the hinterland. These storms typically affect long stretches (∼100 km) of sandy coastlines with variable topo-bathymetries. The large spatial scale makes it computationally challenging for process-based morphological models to be used for predicting dune erosion in early warning systems or probabilistic assessments. To alleviate this, we take a first step to enable efficient estimation of dune erosion using the Dutch coast as a case study, due to the availability of a large topo-bathymetric dataset. Using clustering techniques, we reduce 1,430 elevation profiles in this dataset to a set of typological coastal profiles (TCPs), that can be employed to represent dune erosion dynamics along the whole coast. To do so, we use the topo-bathymetric profiles and historic offshore wave and water level conditions, along with simulations of dune erosion for a number of representative storms to characterize each profile. First, we identify the most important drivers of dune erosion variability at the Dutch coast, which are identified as the pre-storm beach geometry, nearshore slope, tidal level and profile orientation. Then using clustering methods, we produce various sets of TCPs, and we test how well they represent dune morphodynamics by cross-validation on the basis of a benchmark set of dune erosion simulations. We find good prediction skill (0.83) with 100 TCPs, representing a 93% input and associated computational costs reduction. These TCPs can be used in a probabilistic model forced with a range of offshore storm conditions, enabling national scale coastal risk assessments. Additionally, the presented techniques could be used in a global context, utilizing elevation data from diverse sandy coastlines to obtain a first order prediction of dune erosion around the world.
AB - Dune erosion driven by extreme marine storms can damage local infrastructure or ecosystems and affect the long-term flood safety of the hinterland. These storms typically affect long stretches (∼100 km) of sandy coastlines with variable topo-bathymetries. The large spatial scale makes it computationally challenging for process-based morphological models to be used for predicting dune erosion in early warning systems or probabilistic assessments. To alleviate this, we take a first step to enable efficient estimation of dune erosion using the Dutch coast as a case study, due to the availability of a large topo-bathymetric dataset. Using clustering techniques, we reduce 1,430 elevation profiles in this dataset to a set of typological coastal profiles (TCPs), that can be employed to represent dune erosion dynamics along the whole coast. To do so, we use the topo-bathymetric profiles and historic offshore wave and water level conditions, along with simulations of dune erosion for a number of representative storms to characterize each profile. First, we identify the most important drivers of dune erosion variability at the Dutch coast, which are identified as the pre-storm beach geometry, nearshore slope, tidal level and profile orientation. Then using clustering methods, we produce various sets of TCPs, and we test how well they represent dune morphodynamics by cross-validation on the basis of a benchmark set of dune erosion simulations. We find good prediction skill (0.83) with 100 TCPs, representing a 93% input and associated computational costs reduction. These TCPs can be used in a probabilistic model forced with a range of offshore storm conditions, enabling national scale coastal risk assessments. Additionally, the presented techniques could be used in a global context, utilizing elevation data from diverse sandy coastlines to obtain a first order prediction of dune erosion around the world.
KW - clustering
KW - data mining
KW - dune erosion
KW - Dutch coast
KW - K-means
KW - XBeach
UR - http://www.scopus.com/inward/record.url?scp=85116943766&partnerID=8YFLogxK
U2 - 10.3389/fmars.2021.747754
DO - 10.3389/fmars.2021.747754
M3 - Article
AN - SCOPUS:85116943766
SN - 2296-7745
VL - 8
JO - Frontiers in Marine Science
JF - Frontiers in Marine Science
M1 - 747754
ER -