Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific

Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific

We investigated the tsunami hazard in the remote French territory of Wallis and Futuna, Southwest Pacific, using the Gerris flow solver to produce numerical models of tsunami generation, propagation and inundation. Wallis consists of the inhabited volcanic island of Uvéa that is surrounded by a lago...

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Main Authors: G. Lamarche, S. Popinet, B. Pelletier, J. Mountjoy, J. Goff, S. Delaux, J. Bind
Format: Article
Language:English
Published: Copernicus Publications 2015-08-01
Series:Natural Hazards and Earth System Sciences
Online Access:http://www.nat-hazards-earth-syst-sci.net/15/1763/2015/nhess-15-1763-2015.pdf
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spelling doaj-13abfc3171094f35a19c098cb4ba02cd2020-11-24T20:44:47ZengCopernicus PublicationsNatural Hazards and Earth System Sciences1561-86331684-99812015-08-011581763178410.5194/nhess-15-1763-2015Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest PacificG. Lamarche0S. Popinet1B. Pelletier2J. Mountjoy3J. Goff4S. Delaux5J. Bind6National Institute of Water {&} Atmospheric (NIWA) Research, 301 Evans Bay Parade, Wellington 6021, New ZealandNational Institute of Water {&} Atmospheric (NIWA) Research, 301 Evans Bay Parade, Wellington 6021, New ZealandInstitut de Recherche pour le Développement, BP A5, Nouméa, New CaledoniaNational Institute of Water {&} Atmospheric (NIWA) Research, 301 Evans Bay Parade, Wellington 6021, New ZealandSchool of Biological, Earth and Environmental Sciences, UNSW Australia, Sydney 2052, AustraliaNational Institute of Water {&} Atmospheric (NIWA) Research, 301 Evans Bay Parade, Wellington 6021, New ZealandNIWA, 10 Kyle Street, Christchurch 8011, New ZealandWe investigated the tsunami hazard in the remote French territory of Wallis and Futuna, Southwest Pacific, using the Gerris flow solver to produce numerical models of tsunami generation, propagation and inundation. Wallis consists of the inhabited volcanic island of Uvéa that is surrounded by a lagoon delimited by a barrier reef. Futuna and the island of Alofi form the Horn Archipelago located ca. 240 km east of Wallis. They are surrounded by a narrow fringing reef. Futuna and Alofi emerge from the North Fiji Transform Fault that marks the seismically active Pacific-Australia plate boundary. We generated 15 tsunami scenarios. For each, we calculated maximum wave elevation (MWE), inundation distance and expected time of arrival (ETA). The tsunami sources were local, regional and distant earthquake faults located along the Pacific Rim. In Wallis, the outer reef may experience 6.8 m-high MWE. Uvéa is protected by the barrier reef and the lagoon, but inundation depths of 2–3 m occur in several coastal areas. In Futuna, flow depths exceeding 2 m are modelled in several populated areas, and have been confirmed by a post-September 2009 South Pacific tsunami survey. The channel between the islands of Futuna and Alofi amplified the 2009 tsunami, which resulted in inundation distance of almost 100 m and MWE of 4.4 m. This first ever tsunami hazard modelling study of Wallis and Futuna compares well with palaeotsunamis recognised on both islands and observation of the impact of the 2009 South Pacific tsunami. The study provides evidence for the mitigating effect of barrier and fringing reefs from tsunamis.http://www.nat-hazards-earth-syst-sci.net/15/1763/2015/nhess-15-1763-2015.pdf
collection DOAJ
language English
format Article
sources DOAJ
author G. Lamarche
S. Popinet
B. Pelletier
J. Mountjoy
J. Goff
S. Delaux
J. Bind
spellingShingle G. Lamarche
S. Popinet
B. Pelletier
J. Mountjoy
J. Goff
S. Delaux
J. Bind
Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific
Natural Hazards and Earth System Sciences
author_facet G. Lamarche
S. Popinet
B. Pelletier
J. Mountjoy
J. Goff
S. Delaux
J. Bind
author_sort G. Lamarche
title Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific
title_short Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific
title_full Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific
title_fullStr Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific
title_full_unstemmed Scenario-based numerical modelling and the palaeo-historic record of tsunamis in Wallis and Futuna, Southwest Pacific
title_sort scenario-based numerical modelling and the palaeo-historic record of tsunamis in wallis and futuna, southwest pacific
publisher Copernicus Publications
series Natural Hazards and Earth System Sciences
issn 1561-8633
1684-9981
publishDate 2015-08-01
description We investigated the tsunami hazard in the remote French territory of Wallis and Futuna, Southwest Pacific, using the Gerris flow solver to produce numerical models of tsunami generation, propagation and inundation. Wallis consists of the inhabited volcanic island of Uvéa that is surrounded by a lagoon delimited by a barrier reef. Futuna and the island of Alofi form the Horn Archipelago located ca. 240 km east of Wallis. They are surrounded by a narrow fringing reef. Futuna and Alofi emerge from the North Fiji Transform Fault that marks the seismically active Pacific-Australia plate boundary. We generated 15 tsunami scenarios. For each, we calculated maximum wave elevation (MWE), inundation distance and expected time of arrival (ETA). The tsunami sources were local, regional and distant earthquake faults located along the Pacific Rim. In Wallis, the outer reef may experience 6.8 m-high MWE. Uvéa is protected by the barrier reef and the lagoon, but inundation depths of 2–3 m occur in several coastal areas. In Futuna, flow depths exceeding 2 m are modelled in several populated areas, and have been confirmed by a post-September 2009 South Pacific tsunami survey. The channel between the islands of Futuna and Alofi amplified the 2009 tsunami, which resulted in inundation distance of almost 100 m and MWE of 4.4 m. This first ever tsunami hazard modelling study of Wallis and Futuna compares well with palaeotsunamis recognised on both islands and observation of the impact of the 2009 South Pacific tsunami. The study provides evidence for the mitigating effect of barrier and fringing reefs from tsunamis.
url http://www.nat-hazards-earth-syst-sci.net/15/1763/2015/nhess-15-1763-2015.pdf
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