Regional and global tsunami hazard analysis requires simplified and efficient methods for estimating the tsunami inundation height and its related uncertainty. One such approach is the amplification factor (AF) method. Amplification factors describe the relation between offshore wave height and the maximum inundation height, as predicted by linearized plane wave models employed for incident waves with different wave characteristics. In this study, a new amplification factor method is developed that takes into account the offshore bathymetry proximal to the coastal site. The present AFs cover the NorthEastern Atlantic and Mediterranean (NEAM) region. The model is the first general approximate model that quantifies inundation height uncertainty. Uncertainty quantification is carried out by analyzing the inundation height variability in more than 500 high-resolution inundation simulations at six different coastal sites. The inundation simulations are undertaken with different earthquake sources in order to produce different wave period and polarity. We show that the probability density of the maximum inundation height can be modeled with a log-normal distribution, whose median is quite well predicted by the AF. It is further demonstrated that the associated maximum inundation height uncertainties are significant and must be accounted for in tsunami hazard analysis. The application to the recently developed TSUMAPS-NEAM probabilistic tsunami hazard analysis (PTHA) is presented as a use case.
Abstract. In this paper, we present a deterministic approach to tsunami hazard assessment for the city and harbour of Sines, Portugal, one of the test sites of project ASTARTE (Assessment, STrategy And Risk Reduction for Tsunamis in Europe). Sines has one of the most important deepwater ports, which has oil-bearing, petrochemical, liquidbulk, coal, and container terminals. The port and its industrial infrastructures face the ocean southwest towards the main seismogenic sources. This work considers two different seismic zones: the Southwest Iberian Margin and the Gloria Fault. Within these two regions, we selected a total of six scenarios to assess the tsunami impact at the test site. The tsunami simulations are computed using NSWING, a Non-linear Shallow Water model wIth Nested Grids. In this study, the static effect of tides is analysed for three different tidal stages: MLLW (mean lower low water), MSL (mean sea level), and MHHW (mean higher high water). For each scenario, the tsunami hazard is described by maximum values of wave height, flow depth, drawback, maximum inundation area and run-up. Synthetic waveforms are computed at virtual tide gauges at specific locations outside and inside the harbour. The final results describe the impact at the Sines test site considering the single scenarios at mean sea level, the aggregate scenario, and the influence of the tide on the aggregate scenario. The results confirm the composite source of Horseshoe and Marques de Pombal faults as the worst-case scenario, with wave heights of over 10 m, which reach the coast approximately 22 min after the rupture. It dominates the aggregate scenario by about 60 % of the impact area at the test site, considering maximum wave height and maximum flow depth. The HSMPF scenario inundates a total area of 3.5 km 2 .
View related articles View Crossmark data Citing articles: 4 View citing articles On the construction and use of a Paleo-DEM to reproduce tsunami inundation in a historical urban environmentthe case of the 1755 Lisbon tsunami in Cascais
Abstract. The segment of the Africa–Eurasia plate boundary between the
Gloria Fault and the Strait of Gibraltar has been the setting of significant
tsunamigenic earthquakes. However, their precise location and rupture
mechanism remain poorly understood. The investigation of each event
contributes to a better understanding of the structure of this diffuse plate
boundary and ultimately leads to a better evaluation of the seismic and
tsunami hazard. The 31 March 1761 event is one of the few known
transatlantic tsunamis. Macroseismic data and tsunami travel times were used
in previous studies to assess its source area. However, no one discussed the
geological source of this event. In this study, we present a reappraisal of
tsunami data to show that the observations data set is compatible with a
geological source close to Coral Patch and Ampere seamounts. We constrain the
rupture mechanism with plate kinematics and the tectonic setting of the area.
This study favours the hypothesis that the 1761 event occurred in the
southwest of the likely location of the 1 November 1755 earthquake in a
slow deforming compressive regime driven by the dextral transpressive
collision between Africa and Eurasia.
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