Developments in large-scale coastal flood hazard mapping

Developments in large-scale coastal flood hazard mapping

Coastal flooding related to marine extreme events has severe socioeconomic impacts, and even though the latter are projected to increase under the changing climate, there is a clear deficit of information and predictive capacity related to coastal flood mapping. The present contribution reports on e...

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Main Authors: M. I. Vousdoukas, E. Voukouvalas, L. Mentaschi, F. Dottori, A. Giardino, D. Bouziotas, A. Bianchi, P. Salamon, L. Feyen
Format: Article
Language:English
Published: Copernicus Publications 2016-08-01
Series:Natural Hazards and Earth System Sciences
Online Access:http://www.nat-hazards-earth-syst-sci.net/16/1841/2016/nhess-16-1841-2016.pdf
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spelling doaj-555c2471d48a46f7a7894933d7c539de2020-11-24T23:28:13ZengCopernicus PublicationsNatural Hazards and Earth System Sciences1561-86331684-99812016-08-011681841185310.5194/nhess-16-1841-2016Developments in large-scale coastal flood hazard mappingM. I. Vousdoukas0E. Voukouvalas1L. Mentaschi2F. Dottori3A. Giardino4D. Bouziotas5A. Bianchi6P. Salamon7L. Feyen8European Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyDeltares, P.O. Box 177, 2600 MH Delft, the NetherlandsEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyEuropean Commission, Joint European Research Centre (JRC), Via Enrico Fermi 2749, 21027, Ispra, ItalyCoastal flooding related to marine extreme events has severe socioeconomic impacts, and even though the latter are projected to increase under the changing climate, there is a clear deficit of information and predictive capacity related to coastal flood mapping. The present contribution reports on efforts towards a new methodology for mapping coastal flood hazard at European scale, combining (i) the contribution of waves to the total water level; (ii) improved inundation modeling; and (iii) an open, physics-based framework which can be constantly upgraded, whenever new and more accurate data become available. Four inundation approaches of gradually increasing complexity and computational costs were evaluated in terms of their applicability to large-scale coastal flooding mapping: static inundation (SM); a semi-dynamic method, considering the water volume discharge over the dykes (VD); the flood intensity index approach (Iw); and the model LISFLOOD-FP (LFP). A validation test performed against observed flood extents during the Xynthia storm event showed that SM and VD can lead to an overestimation of flood extents by 232 and 209 %, while Iw and LFP showed satisfactory predictive skill. Application at pan-European scale for the present-day 100-year event confirmed that static approaches can overestimate flood extents by 56 % compared to LFP; however, Iw can deliver results of reasonable accuracy in cases when reduced computational costs are a priority. Moreover, omitting the wave contribution in the extreme total water level (TWL) can result in a  ∼  60 % underestimation of the flooded area. The present findings have implications for impact assessment studies, since combination of the estimated inundation maps with population exposure maps revealed differences in the estimated number of people affected within the 20–70 % range.http://www.nat-hazards-earth-syst-sci.net/16/1841/2016/nhess-16-1841-2016.pdf
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language English
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author M. I. Vousdoukas
E. Voukouvalas
L. Mentaschi
F. Dottori
A. Giardino
D. Bouziotas
A. Bianchi
P. Salamon
L. Feyen
spellingShingle M. I. Vousdoukas
E. Voukouvalas
L. Mentaschi
F. Dottori
A. Giardino
D. Bouziotas
A. Bianchi
P. Salamon
L. Feyen
Developments in large-scale coastal flood hazard mapping
Natural Hazards and Earth System Sciences
author_facet M. I. Vousdoukas
E. Voukouvalas
L. Mentaschi
F. Dottori
A. Giardino
D. Bouziotas
A. Bianchi
P. Salamon
L. Feyen
author_sort M. I. Vousdoukas
title Developments in large-scale coastal flood hazard mapping
title_short Developments in large-scale coastal flood hazard mapping
title_full Developments in large-scale coastal flood hazard mapping
title_fullStr Developments in large-scale coastal flood hazard mapping
title_full_unstemmed Developments in large-scale coastal flood hazard mapping
title_sort developments in large-scale coastal flood hazard mapping
publisher Copernicus Publications
series Natural Hazards and Earth System Sciences
issn 1561-8633
1684-9981
publishDate 2016-08-01
description Coastal flooding related to marine extreme events has severe socioeconomic impacts, and even though the latter are projected to increase under the changing climate, there is a clear deficit of information and predictive capacity related to coastal flood mapping. The present contribution reports on efforts towards a new methodology for mapping coastal flood hazard at European scale, combining (i) the contribution of waves to the total water level; (ii) improved inundation modeling; and (iii) an open, physics-based framework which can be constantly upgraded, whenever new and more accurate data become available. Four inundation approaches of gradually increasing complexity and computational costs were evaluated in terms of their applicability to large-scale coastal flooding mapping: static inundation (SM); a semi-dynamic method, considering the water volume discharge over the dykes (VD); the flood intensity index approach (Iw); and the model LISFLOOD-FP (LFP). A validation test performed against observed flood extents during the Xynthia storm event showed that SM and VD can lead to an overestimation of flood extents by 232 and 209 %, while Iw and LFP showed satisfactory predictive skill. Application at pan-European scale for the present-day 100-year event confirmed that static approaches can overestimate flood extents by 56 % compared to LFP; however, Iw can deliver results of reasonable accuracy in cases when reduced computational costs are a priority. Moreover, omitting the wave contribution in the extreme total water level (TWL) can result in a  ∼  60 % underestimation of the flooded area. The present findings have implications for impact assessment studies, since combination of the estimated inundation maps with population exposure maps revealed differences in the estimated number of people affected within the 20–70 % range.
url http://www.nat-hazards-earth-syst-sci.net/16/1841/2016/nhess-16-1841-2016.pdf
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