Your search keyword '"TSUNAMI HAZARD"' showing total 150 results

1. A review of tsunami hazard for southern Aotearoa New Zealand with implications for future research.

Author

Orchiston, Caroline, Cochran, Ursula, and Vause, Ashleigh

Subjects

*TSUNAMI hazard zones, *EMERGENCY management, *SUBDUCTION zones, *TSUNAMI warning systems, *SEISMOGRAMS, *TSUNAMIS, *FLOODS

Abstract

Here we provide an overview of southern Aotearoa New Zealand’s tsunami hazard to promote awareness, enable enhanced preparation, and to act as a resource for further research. The Southland region of Aotearoa has a long length of coastline exposed to local, regional, and distant tsunami sources. In comparison with regions further north, Southland’s tsunami hazard has received less scientific attention. Information gathered from the National Tsunami Hazard Model 2021, tsunami databases, and local studies, indicates that Southland has a high tsunami hazard. Tsunami heights of 4–12 m can be expected at a 2500-year return period. Earthquakes at the Puysegur and Peru subduction zones are the most significant tsunami sources for Southland. Modelling of tsunamis triggered by great earthquakes at these boundaries suggests inundation of low-lying land is likely, especially around Invercargill and Riverton. Surveys of residents conducted by local authorities suggest tsunami preparedness is inadequate. Geological records of large earthquakes and tsunamis are lacking for Southland, and we acknowledge that such physical evidence has been important for education and preparedness campaigns in other parts of the country. However, we argue that the level of hazard is sufficient to warrant increased collaboration between scientists, emergency managers, and communities to improve preparedness. [ABSTRACT FROM AUTHOR]

Published

2024

2. Probabilistic Connectivity Assessment of Road Networks Subjected to Ground Motion and Tsunamis Considering the Spatial Correlations among Hazard Intensities.

Author

Aoki, Koki, Akiyama, Mitsuyoshi, Alhamid, Abdul Kadir, Frangopol, Dan M., and Koshimura, Shunichi

Subjects

EARTHQUAKE hazard analysis, TSUNAMI warning systems, GROUND motion, TSUNAMIS, EARTHQUAKES

Abstract

Before the anticipated Nankai Trough earthquake, the effects of multiple cascading hazards on bridge performance and the associated functionalities of road networks must be assessed to develop recovery strategies. This paper presents a framework for assessing the probabilistic connectivity of road networks exposed to both ground motion and tsunami, considering the spatial correlations among hazard intensities. To evaluate the joint probabilities of bridge states (i.e., passable and impassable states) and the probabilistic connectivity of road networks, the total probability theorem was used to integrate spatially correlated seismic and tsunami hazard assessments into the fragility estimates that consider the cascading effects of ground motion and tsunami-induced damages to bridges. For illustrative purposes, the probabilistic connectivity of hypothetical road networks in Japan that could be affected by both ground motion and tsunami during the anticipated Nankai Trough earthquake was assessed using the proposed method. The results showed that seismic retrofitting of bridges located along the route where the probability of impassable states due to tsunami is very low can enhance the probabilistic connectivity of entire road networks. [ABSTRACT FROM AUTHOR]

Published

2024

3. Tsunami hazard evaluation of river embankment structures incorporating their vulnerability to seismic strong motion.

Author

Imai, Kentaro, Nakai, Kentaro, Hirai, Takashi, Noda, Toshihiro, Arai, Nobuo, Iwama, Shunji, Iwase, Hiroyuki, and Baba, Toshitaka

Subjects

SHALLOW-water equations, ALLUVIAL plains, EARTHQUAKES, EMBANKMENTS, COASTAL development, TSUNAMIS, EARTHQUAKE hazard analysis

Abstract

Development of coastal areas in Japan for various land uses since the 1960s has contributed to industrial upgrades and improved the efficiency of transportation networks. However, there are concerns about the vulnerability of developments on alluvial plains and reclaimed lands to geological events, like ground subsidence due to liquefaction during large earthquakes. Realistic assessment of earthquake and tsunami hazards and evaluation of possible countermeasures require accurate estimation of the amount of subsidence that can be expected from liquefaction at coastal and riverside sites supporting various structures. In this study, to evaluate the amount a river embankment structure might be expected to settle as a result of strong motion from an assumed Nankai Trough great earthquake, we conducted a numerical simulation using the soil–water coupled finite deformation analysis code GEOASIA. We then investigated the effect of the estimated embankment subsidence on tsunami inundation, which was simulated by using nonlinear shallow-water equations and a grid spacing as fine as 3.3 m. The influence of urban structures on the inundated area was taken into account by using a structure-embedded elevation model (SEM). The results showed that subsidence of river embankments and the collapse of parapet walls on top of them would increase both the depth and area of inundation caused by a tsunami triggered by a Nankai Trough scenario earthquake. Our findings underscore the importance of evaluating not only earthquake resistance but also vulnerability of coastal and riverside structures to strong motion in tsunami hazard analyses. Furthermore, the importance of tsunami inundation analysis using a SEM for predicting the behavior of tsunami flotsam in urban areas was demonstrated. [ABSTRACT FROM AUTHOR]

Published

2024

4. Probabilistic tsunami hazard assessment for the makran subduction zone using logic tree and stochastic rupture sources.

Author

Momeni, Payam and Goda, Katsuichiro

Subjects

*TSUNAMI warning systems, *TSUNAMI hazard zones, *SUBDUCTION zones, *TSUNAMIS, *RISK assessment, *WATER depth, *EARTHQUAKES, *STOCHASTIC models

Abstract

The Makran Subduction Zone (MSZ) in the northwestern Indian Ocean can generate large tsunamigenic thrust earthquakes affecting the coastal regions of Pakistan, Iran, Oman, and western India. In this paper, a probabilistic tsunami hazard assessment is conducted for the MSZ using stochastic tsunami simulations of moment magnitude (Mw) of 7.7–9.1 earthquake scenarios. This study investigates uncertainties associated with earthquake occurrence rate, single-segment (eastern and western MSZ) or two-segment (full MSZ) rupture scenarios, source geometry, and slip heterogeneity. The total number of simulated source models is 15,000. This study presents two major categories of results: stochastic source models and ranges of 475, 975, and 2475-year tsunami heights. For instance, tsunami heights generated by Mw 8.5‒8.7 stochastic sources of western MSZ vary between 1 m and 10 m with a mean of ~ 4.5 m in the affected areas. The tsunami heights are sensitive to the source models' characteristics, such as location of the large slip areas, bathymetry of the nearshore area, and the location of bays. Considering different occurrence rates results in significant variability in the estimated 475, 975, and 2475-year tsunami heights. For example, 2475-year tsunami height in Chabahar is in the range of 3‒7.4 m at 10 m water depth. [ABSTRACT FROM AUTHOR]

Published

2024

5. Possible Maximum Earthquake Tsunami Along the South Coast of China Inferred From GPS‐Derived Surface Velocities.

Author

Zhao, G. and Niu, X.

Subjects

TSUNAMI warning systems, TSUNAMIS, EARTHQUAKES, EARTHQUAKE magnitude, SEISMOTECTONICS, COASTS, VELOCITY

Abstract

This study aims to assess the tsunami hazard of the maximum possible earthquake along the south coast of China. GPS‐derived surface velocities around the Manila Trench have been used to clarify the active tectonics and estimate the seismic potential of Manila subduction, where catastrophic tsunamis may originate and cause devastating damage to the surrounding area of the South China Sea. Based on the maximum potential earthquake magnitude estimated from the accumulated seismic moment, more than 100,000 possible tsunami scenarios with varying epicenters have been simulated considering the slip heterogeneity. The impact of several uncertain parameters including the release period and release ratio of accumulated seismic moment are investigated, as well as some assumptions in the model of tsunami generation. Although different release conditions for accumulated seismic moment result in a significant impact on the value of tsunami height, similar trend in spatial distribution has been shown. The results show that the tsunami wave height along the south coast of China has an increasing trend from west to east, with the maximum tsunami wave height exceeding 10 m corresponding to the potential earthquake Mw = 9.1 with a 1,000‐year release period. The impact of fault slip heterogeneity on tsunami wave height is significant. Compared to uniform slip, considering stochastic slip will increase the average tsunami wave height by about 15%. Considering locking distribution will increase the average tsunami wave height by about 20%–30% and also increase the maximum tsunami wave height by about 60%–70%. Plain Language Summary: The purpose of this study is to evaluate the tsunami hazard of the maximum possible earthquake along the south coast of China. The Manila Trench is the potential tsunami source. The first problem to be solved in the study is how large the maximum earthquake is in the Manila Trench. Therefore, the study first uses the horizontal velocity data observed by GPS stations to invert the degree of locking on the fault plane. The rate of accumulated energy is estimated based on the degree of fault locking, and then the maximum magnitude of earthquakes that may occur on the fault with different release periods is estimated. The subsequent issue to be solved is how large the tsunami generated by the maximum earthquake is. In order to fully consider the randomness of slip, the study simulated more than 100,000 possible tsunami scenarios for each earthquake magnitude. The results indicate that only considering uniform slip will significantly underestimate the tsunami hazard along the south coast of China. Key Points: Fault locking inverted by GPS‐derived surface velocities is used to estimate the seismic potential and as constraints on stochastic slipTsunami scenarios with varying epicenters and the slip heterogeneity are simulated for each estimated maximum earthquake magnitudeSensitivity analysis has been conducted considering the release period and the release ratio of accumulated seismic moment [ABSTRACT FROM AUTHOR]

Published

2024

6. Tsunami insurance portfolio optimization for coastal residential buildings under non-stationary sea level rise effects based on sample average approximation.

Author

Alhamid, Abdul Kadir, Akiyama, Mitsuyoshi, Koshimura, Shunichi, Frangopol, Dan M., and So, Higuma

Subjects

*TSUNAMIS, *SEA level, *ABSOLUTE sea level change, *DISASTER insurance, *DWELLINGS

Abstract

The devastating consequences of tsunamis on coastal infrastructure have highlighted the urgent need for effective disaster risk reduction strategies. To mitigate tsunami disasters, the insurance industry plays a vital role in implementing risk transfer measures by providing financial protection against asset damage. However, the current research on catastrophe insurance policies for coastal infrastructure lacks consideration of climate change effects. It is essential to take into account the non-stationary effects of sea-level rise to develop long-term tsunami disaster mitigation measures and promote socioeconomic resilience in coastal communities. This paper aims to provide an insurance portfolio optimization framework for coastal residential buildings subjected to tsunamis considering non-stationary sea-level rise effects based on a stochastic simulation approach. A spatiotemporal probabilistic sea-level rise hazard assessment is carried out by utilizing available climate models and considering several emission scenarios. Tsunami propagation analyses under various sea-level rise cases are performed to evaluate the time-variant tsunami hazard curves based on Monte Carlo simulation. A life cycle-based stochastic insurance claim model associated with the cumulative loss of building assets is developed based on a non-stationary compound renewal process. Finally, a sample average approximation method is leveraged to estimate the optimum basic insurance premium rate by maximizing the insurer's profit under a cost-constrained insurance purchase decision of homeowners. As a case study, the proposed framework is applied to multiple municipalities situated in the tsunami-prone region of Kochi Prefecture, Japan. Sea-level rise substantially decreases the maximum profits of tsunami insurers and increases the premium rate and ruin probability. [ABSTRACT FROM AUTHOR]

Published

2024

7. Forearc crustal faulting and estimated worst-case tsunami scenario in the upper plate of subduction zones. Case study of the Morne Piton Fault system (Lesser Antilles, Guadeloupe Archipelago).

Author

Philippon, Melody, Roger, Jean, Lebrun, Jean-Frederic, Thinon, Isabelle, Foix, Oceane, Mazzotti, Stephane, Gutscher, Marc-Anadre, Montheil, Leny, and Cornee, Jean-Jacques

Subjects

PALEOSEISMOLOGY, TSUNAMIS, SUBDUCTION zones, ARCHIPELAGOES, WATER depth, EARTHQUAKES

Abstract

In this study, alternatively to the megathrust, we identify upper plate normal faults orthogonal to the trench as a possible tsunami source along the Lesser Antilles subduction zone. We study the Morne Piton Fault system, a trench-perpendicular upper crustal fault affecting the Lesser Antilles forearc at the latitude of Guadeloupe. By the means of seismic reflection, high resolution bathymetry, Remotely Operated Vehicle images and dating, we reassess the slip rate of the Morne Piton Fault at 0.2 mm.yr-1 since fault inception (i.e. 7 Ma), dividing by five previous estimations and thus increasing the earthquake time recurrence and lowering the associated hazard. We evidence a metric scarp with striae at the toe of the Morne Piton Fault system suggesting a recent fault rupture. We estimate a fault rupture area of ~ 450-675 km2 and then a magnitude range for the seismic event around Mw 6.5 ± 0.5. We present results from a multi-segment tsunami model representative for the worst-case scenario which gives an overview of what could happen in terms of tsunami generation if the whole identified Morne Piton Fault segments ruptured together. Our model illustrates the potential impact of local tsunamis on the surrounding coastal area as well as local bathymetric controls on tsunami propagation as (i) shallow water plateaus act as secondary sources and are responsible for a wrapping of the tsunami waves around the island of Marie-Galante, (ii) canyons are focusing and enhancing the wave height in front of the most touristic and populated town of the island, (iii) a resonance phenomenon is observed within Les Saintes archipelago showing that the waves' frequency content is able to perturbate the sea-level during many hours after the seismic rupture. [ABSTRACT FROM AUTHOR]

Published

2024

8. IMPACT OF LAND USE CHANGES ON THE TSUNAMI HAZARDS IN PART OF COASTAL KEBUMEN.

Author

Pamungkas, Bagus, Mardiatno, Djati, and Retnowati, Arry

Subjects

*HAZARD mitigation, *TSUNAMI warning systems, *TSUNAMI hazard zones, *LAND use, *TSUNAMIS, *GEOGRAPHIC information systems, *REMOTE-sensing images

Abstract

This research was conducted to analyze land use change from 2016 to 2022 and their impact on the tsunami hazard zone on the coast of Kebumen Regency. For land use change analysis, remote sensing, geographic information systems (GIS), and statistical tests were applied to Sentinel-2A satellite imagery. The tsunami hazard was simulated using tsunami inundation modeling based on land use spatial data and DEMNAS processed using GIS. Land use changes occurred significantly in the study area, especially in Mirit District. The Southern Cross Road (JJLS) and coastal morphological conditions influence land use change patterns. Land use changes impact changes in the tsunami hazard zone, especially in the use of fir forests and shrimp ponds. The research findings can be used as input for developing a tsunami disaster mitigation plan and detailed spatial planning on the coast of Kebumen Regency. [ABSTRACT FROM AUTHOR]

Published

2023

9. Modeling the potential genesis of tsunamis from below an accretionary prism and their potential impact: a case study along the eastern boundary of the Caribbean Plate.

Author

Rashidi, Amin, Dutykh, Denys, and Beck, Christian

Subjects

SUBDUCTION zones, TSUNAMIS, SEDIMENT transport, SHEARING force, PRISMS, EARTHQUAKES, SUBDUCTION

Abstract

The Lesser Antilles subduction zone marks the convergence between the Caribbean Plate and the oceanic Atlantic part of the America Plate. A specificity of this subduction is the development of a huge accretionary prism, the Barbados complex. As other subduction zones, the Lesser Antilles one has the potential to produce megathrust-associated earthquakes and related tsunamis. This study evaluates the potential hazard of tsunami scenarios along this eastern boundary of the Caribbean Plate, taking into account its specificities. We define six scenarios along the Lesser Antilles subduction zone including three M w 7.5 , 8.0 and 8.5 earthquake models, in both northern and southern parts of the arc. We incorporate in tsunami simulations the effect of sediment amplification in tsunami generation. In the southern half, the thick sediments pile, related to tectonic accretion, appears much more effective than the much thinner accumulation characterizing the northern half. The bed shear stress is also computed in this study as it is an important factor in sediment transport which can show the potential locations for sediment movement by tsunamis. Our results indicate the ability of scenario earthquakes to produce powerful tsunamis. The impacts of northern scenarios on Guadeloupe could be severe (maximum tsunami wave height of > 5 m ), whereas the impacts from southern scenarios are relatively less strong (maximum wave amplitude of < 5 m ). The tsunami waves produced by M w 8.0 and 8.5 appear able to inundate the coast of Sainte-Anne, Guadeloupe, up to 2 km . The distributions of bed shear stress from northern scenarios suggest that the offshore Leeward Islands could be potentially prone to sediment transport as possible tsunami deposits have been found in the region in former geological studies. [ABSTRACT FROM AUTHOR]

Published

2023

10. Tsunami Recurrence and Hazard Evaluation for the South Kuril Islands.

Author

Kaistrenko, Victor

Subjects

*TSUNAMI warning systems, *TSUNAMIS, *REGIONAL development, *ISLANDS, *RISK assessment, *HAZARDS

Abstract

Probabilistic Tsunami Hazard Assessment (PTHA) is used to estimate tsunami recurrence and hazard for the South Kuril Islands. The method is a further development and improvement of the Regional Statistical Tsunami Model (RSTM) developed earlier [Kaistrenko (Pure Appl Geophys 168:2065–2069, 2011) and (Pure Appl Geophys 171:3527–3538, 2014)], which differs from the commonly used variations of PTHA and is entirely based on historical tsunami observations. The method operates with tsunami height datasets exceeding a threshold height of 0.5 m and ranked in height, for each coastal location of the region. This condition is crucial; incorrect or imprecise results can arise from incomplete datasets. Based on observations from 63 coastal locations in the South Kuril region, it is shown that all ranked tsunami height data provided by existing tsunami catalogues for a period of 67 years, can be described by a single regional recurrence function. This function contains two types of scale parameters: (1) the asymptotic frequency, f, of major tsunamis in the study region, and (2) the set of characteristic tsunami heights, H*, for all locations considered. The dependences of the parameters f and H* on the observation period and amount of data were examined. As an example of the method, we construct a preliminary tsunami hazard map for the South Kuril Islands and analyze the possible errors of the estimated tsunami parameters and resulting tsunami recurrence. [ABSTRACT FROM AUTHOR]

Published

2023

11. Life‐cycle risk assessment of building portfolios subjected to tsunamis under non‐stationary sea‐level rise based on a compound renewal process.

Author

Alhamid, Abdul Kadir, Akiyama, Mitsuyoshi, Aoki, Koki, Koshimura, Shunichi, and Frangopol, Dan M.

Subjects

ABSOLUTE sea level change, TSUNAMIS, TSUNAMI warning systems, PRODUCT life cycle assessment, RISK assessment, HAZARD mitigation, INFRASTRUCTURE (Economics)

Abstract

The immense impacts of tsunamis can inflict substantial damage on coastal infrastructure systems during their lifetime and lead to considerable economic loss. However, with the increasing intensity and variability of sea‐level rise due to climate change, evaluations of the life‐cycle tsunami risk associated with cumulative loss have become increasingly complex since tsunami hazards are time‐dependent. In addition, the number of earthquake events and the corresponding arrival times are substantially uncertain. Therefore, an accurate life‐cycle tsunami risk assessment methodology should be established to appropriately develop disaster mitigation measures. This paper provides a novel life‐cycle risk assessment of building portfolios subjected to tsunami hazards under non‐stationary sea‐level rise effects due to climate change. The cumulative loss of a building portfolio is evaluated through a compound renewal process based on earthquake interarrival time uncertainties and time‐dependent risk. The earthquake interarrival times are modeled using a non‐Poisson process based on historical data. Tsunami hazard curves that consider the effects of sea‐level rise, estimated based on climate models, are obtained with tsunami propagation analysis. The time‐variant annual risk is estimated based on reliability and building unit loss. Finally, a numerical procedure is proposed to estimate the life‐cycle tsunami risk of building portfolios. An illustrative example is provided by applying the framework to several municipalities in the Kochi Prefecture of Japan to assess the effects of climate change on the life‐cycle tsunami risk. [ABSTRACT FROM AUTHOR]

Published

2023

12. Estimating Earthquake-Induced Tsunami Height Probabilities without Sampling.

Author

Tong, Shanyin, Vanden-Eijnden, Eric, and Stadler, Georg

Subjects

*TSUNAMIS, *SHALLOW-water equations, *LOGNORMAL distribution, *PROBABILITY theory

Abstract

Given a distribution of earthquake-induced seafloor elevations, we present a method to compute the probability of the resulting tsunamis reaching a certain size on shore. Instead of sampling, the proposed method relies on optimization to compute the most likely fault slips that result in a seafloor deformation inducing a large tsunami wave. We model tsunamis induced by bathymetry change using the shallow water equations on an idealized slice through the sea. The earthquake slip model is based on a sum of multivariate log-normal distributions, and follows the Gutenberg-Richter law for seismic moment magnitudes ranging from 7 to 9. For a model problem inspired by the Tohoku-Oki 2011 earthquake and tsunami, we quantify annual probabilities of differently sized tsunami waves. Our method also identifies the most effective tsunami mechanisms. These mechanisms have smoothly varying fault slip patches that lead to an expansive but moderately large bathymetry change. The resulting tsunami waves are compressed as they approach shore and reach close-to-vertical leading wave edge close to shore. [ABSTRACT FROM AUTHOR]

Published

2023

13. Probabilistic Tsunami Risk Assessment from Incomplete and Uncertain Historical Impact Records: Mediterranean and Connected Seas.

Author

Triantafyllou, Ι., Papadopoulos, G. A., and Kijko, A.

Subjects

*EARTHQUAKE hazard analysis, *TSUNAMI hazard zones, *TSUNAMIS, *TSUNAMI damage, *RISK assessment

Abstract

Tsunami risk is considered as the probability of a particular coastline being struck by a tsunami that may cause a certain level of impact (destructiveness). The impact metric of a tsunami is expressed in terms of tsunami intensity values, K, assigned on a 12-degree scale. To calculate tsunami risk we are based on the tsunami history of the region codified in tsunami catalogues. The probabilistic model adopted was used successfully for hazard assessment of earthquakes (Kijko et al. in Bull Seismol Soc Am 79:645–654, 2016) and of tsunamis (Smit et al. in Environmetrics 30:e2566, 2019) by considering seismic magnitude and tsunami height as metrics of the respective hazards. In this model, instead of hazard metrics we inserted risk metric, i.e. wave impact in terms of intensity values. The procedure allows utilization of the entire data set consisting not only from the complete (recent) part of tsunami catalogue but also from the highly incomplete and uncertain historical part of the catalogue. Risk is assessed in terms of probabilities of exceedance and return periods of certain intensity values in specific time frames. We applied the model using catalogues for the Mediterranean and connected seas. Sensitivity analysis showed that using complete data sets generally provided more realistic results than using entire data sets. Results indicated that the risk level depends on the seismicity level and not on the size of individual ocean basin. The highest tsunami risk level was found in the eastern Mediterranean (EM), with a significantly lower risk in the western Mediterranean (WM). In the Marmara Sea (MS), the tsunami risk was low, and the lowest was in the Black Sea (BS). The risk in the small Corinth Gulf (CG, Central Greece) was comparable to that of WM. The return period of damaging tsunamis (i.e. K ≥ 7) was 22 years in the entire Mediterranean basin and 31, 118, 135, 424, and 1660 years in the EM, WM, CG, MS, and BS basins, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

14. Sea-Level Rise Effects on Changing Hazard Exposure to Far-Field Tsunamis in a Volcanic Pacific Island.

Author

Welsh, Rebecca, Williams, Shaun, Bosserelle, Cyprien, Paulik, Ryan, Chan Ting, Josephina, Wild, Alec, and Talia, Lameko

Subjects

TSUNAMI warning systems, FLOOD damage, ABSOLUTE sea level change, TSUNAMIS, SEA level, BUILT environment, ISLANDS, HYDRODYNAMICS

Abstract

Coastal flooding exacerbated by climate change is recognised as a major global threat which is expected to impact more than a quarter of all people currently residing in Pacific Island countries. While most research in the last decade has focused on understanding the dynamics and impacts of future coastal flooding from extreme sea levels, the effects of relative sea level rise (RSLR) on exacerbating tsunami hazards are not well understood. Far-field or distant sourced tsunamis tend to have relatively lower impacts in Pacific Island states compared with locally sourced events, but there is limited understanding of how the impact of far-field tsunamis changes over time due to RSLR. Using the hydrodynamics software BG-Flood, we modelled the Tōhoku-oki tsunami from propagation to inundation in Samoa under incremental SLR to examine the effects that RSLR has on changing the exposure of the built environment (e.g., buildings) to a far-field tsunami. Outputs of maximum tsunami inundation and flow depth intensities which incorporate incremental SLR were then combined with digital representations of buildings and depth-damage functions in the RiskScape multi-hazard risk modelling software to assess the changes in building exposure over time. Results suggest that the impacts of Tōhoku-oki-type far-field tsunamis become significant once RSLR reaches 1 m above present levels. Present-day building exposure will increase by approx. 500% with 1 m RSLR by 2080–2130, and approx. 2350% with 2 m RSLR by as early as 2130–2140. These findings provide useful insights for application to tsunami hazard risk assessments under changing sea level conditions in analogous island environments. [ABSTRACT FROM AUTHOR]

Published

2023

15. Assessing tsunami vertical evacuation processes based on probabilistic tsunami hazard assessment for west coast of Aceh Besar, Indonesia.

Author

Ibrahim, Syamsidik, Azmeri, Hasan, Muttaqin, Irwansyah, Abdullah, and Al Farizi, Muhammad Daffa

Subjects

TSUNAMI warning systems, TSUNAMIS, INDIAN Ocean Tsunami, 2004, CIVILIAN evacuation, RISK assessment

Abstract

Background: Tsunamis are rare events compared to other disasters but have devastating consequences. In the last 100 years, more than 24 tsunamis and more than 235,000 fatalities have occurred globally. Indonesia has a high risk of a tsunami disaster. Since the devastating 2004 tsunami in the Indian Ocean, much research and preparatory work have been done to reduce the impact of future tsunamis in Indonesia, including in the province of Aceh, especially along the western coast where West Aceh is located. This coastal area was destroyed by a tsunami as high as 15–30 m, resulting in the loss of life, housing, tourist areas, industrial areas, and other public facilities. Given that tsunami disasters are rare and sometimes occur long in advance, human memory and awareness are reduced, making research on the level of tsunami awareness of disasters a challenging task. Method: Probabilistic Tsunami Hazard Assessment (PTHA) is a method that has been developed to predict tsunami hazards with a return period of hundreds to thousands of years, beyond the limited availability of historical data. The PTHA method can provide important information that supports tsunami risk management measures. This study aims to estimate recurrence period-based tsunami risk on the west coast of the district of Aceh Besar using the PTHA method. In this study, the source of the tsunami is caused by fault activity at sea. Seven tsunami scenarios based on fault parameters (earthquakes of magnitudes Mw 8.0 to 9.2 with interval 0,2) with the fault location focusing on the Aceh-Andaman Mega Thrust Segment, as applied in this study. This segment was a similar source to the 2004 Indian Ocean tsunami that created a rupture area along a distance of 1155 km, with six parts of the fault. Result: The maximum inundation distance reached 6 km for the flat area, with a flow depth of 13 m. The site has a cliff that is close to the shoreline, with an inundation distance shorter than the distance across the flat area. With an arrival time of less than 25 min, it is recommended to have an evacuation building and evacuation road in a wide inundated area, and an arrangement of hills close to the beach as an evacuation area, in order to reduce the number of casualties. For 100 years return period or exceedance probability rate 0.01, the average flow depth on the coast may exceed 5 m, and the maximum flow depth for a 1000-year return period or annual probability of 0.001 is 12 m. With the potential tsunami in the future, continuous tsunami drills and tsunami education are needed so that people can maintain an awareness of the threat posed by tsunamis. [ABSTRACT FROM AUTHOR]

Published

2023

16. A new tsunami hazard assessment for eastern Makran subduction zone by considering splay faults and applying stochastic modeling.

Author

Momeni, Payam, Goda, Katsuichiro, Mokhtari, Mohammad, and Heidarzadeh, Mohammad

Subjects

*TSUNAMI warning systems, *TSUNAMIS, *SUBDUCTION zones, *TSUNAMI hazard zones, *RISK assessment, *STOCHASTIC models, *SEISMIC surveys, *FAULT location (Engineering)

Abstract

Tsunami hazard imposed by possible rupture of splay faults is important as it may significantly intensify tsunami heights locally. The Makran Subduction Zone (MSZ) in the northwestern Indian Ocean can generate large thrust earthquakes that could trigger significant tsunamis. In this paper, the effects of possible rupture of splay faults on the tsunami hazards of eastern MSZ are studied by developing a framework that uses stochastic earthquake rupture models and considers uncertainties related to rupture location, rupture geometry, seismic moment split ratio, earthquake slip asperity location within a fault plane, and earthquake slip heterogeneity. To quantify these uncertainties, 484 different parameter combinations of tsunami sources are considered systematically. The geometry of splay faults is developed using the most recent marine seismic surveys of the tectonic structure of the MSZ. A moment magnitude of 8.6 is considered as a scenario magnitude. The results of this study are generated in two parts, by considering average sources and stochastic sources. Results show significant local amplification of the maximum tsunami heights due to splay faults. For instance, the maximum wave height in Pasni, Pakistan can be amplified by a factor of four due to a single splay fault rupture scenario of average sources. [ABSTRACT FROM AUTHOR]

Published

2023

17. Stochastic source modeling and tsunami simulations of cascadia subduction earthquakes for Canadian Pacific coast.

Author

Goda, Katsuichiro

Subjects

*TSUNAMIS, *STOCHASTIC models, *DISTRIBUTION (Probability theory), *SUBDUCTION, *SUBDUCTION zones, *EARTHQUAKES

Abstract

This study presents new stochastic source models for the Cascadia subduction earthquakes in the Pacific Northwest, which can trigger massive tsunamis along the shoreline of Vancouver Island. An extensive set of 5,000 stochastic source models is generated for the moment magnitude ranges between 8.1 and 9.1, and regional tsunami hazard simulations are performed at the grid resolution of 270 m. The results from the stochastic tsunami simulations are characterized by evaluating the regional tsunami hazard metric that is based on the geometric mean of the maximum wave heights along the Vancouver Island coast. Subsequently, using the probability distribution of the regional tsunami hazard parameter, representative source models are identified by capturing the average as well as rare rupture cases and then detailed tsunami hazard results, such as maximum wave height maps and wave profiles at specific locations, are examined. Numerical results highlight the directivity effects of tsunami generation and wave propagation on tsunami hazards along the Canadian Pacific coast and the earthquake source characterizations in terms of fault geometry and earthquake slip distribution. The developed source models and tsunami simulation results serve as the first step for performing probabilistic tsunami hazard analysis for the Cascadia subduction zone. [ABSTRACT FROM AUTHOR]

Published

2022

18. Lacustrine mass movements in active tectonic settings: Lake tsunami sources in New Zealand's South Island.

Author

Hughes, Katie E., Fitzsimons, Sean J., and Howarth, Jamie D.

Subjects

*SEISMIC surveys, *MULTIBEAM mapping, *CROWDSOURCING, *RISK assessment, *LAKES, *TSUNAMIS, *TSUNAMI warning systems

Abstract

Lake tsunamis generated from subaerial and subaqueous mass movements can pose a significant hazard to lakeshore communities. However, current knowledge of lake tsunamis is derived from a limited number of studies, primarily in low-seismicity settings such as Switzerland and Norway. Underrepresented are studies from active tectonic settings, characterised by high relief, high sediment yields, and frequent seismic shaking that is likely to produce episodic subaerial and subaqueous mass movements with the potential to produce lake tsunamis. This study seeks to address this gap in our understanding through an examination of four lakes in the active tectonic region of New Zealand's South Island (Lake Rotoiti, Lake Rotoroa, Lake Brunner, and Lake Mapourika). High-resolution multibeam bathymetry and high-resolution seismic reflection data were used to identify and characterize the landforms and sediment associations of large and potentially tsunamigenic mass movements. A qualitative evaluation of the tsunamigenic capacity of the identified mass movements was undertaken using established empirical relationships between mass movement volumes and run-up heights. The bathymetric and seismic surveys have revealed 16 previously undocumented mass movements capable of generating lake tsunami. Fluvial deltas and bedrock slopes proximal to active faults were the most prevalent mass movement source areas, with the largest mass movements identified being a 49 Mm3 delta collapse and a 110 Mm3 subaerial mass movement in Lake Rotoroa. The findings suggest the origin and characteristics of the potentially tsunamigenic mass movements identified were strongly influenced by the high rates of delta progradation, frequent seismic activity, and the preconditioning and displacement by active faults, typical of active tectonic settings. Our results provide new insights into the heterogeneity of lacustrine mass movements and the drivers of lake tsunami hazards in underrepresented high-seismicity regions. The findings illustrate the importance of developing regionally specific insights into lake tsunami susceptibility and may inform the direction of more detailed lake tsunami hazard assessment in New Zealand. [Display omitted] • Multibeam bathymetry and seismic reflection surveys were conducted on four lakes in tectonically active New Zealand. • 16 previously undocumented large and potentially tsunamigenic mass movement deposits were identified. • High sedimentation rates and frequent seismic shaking control large lacustrine mass movements in active tectonic settings. [ABSTRACT FROM AUTHOR]

Published

2024

19. Tsunami Hazard Assessment at Oeiras Municipality, Portugal.

Author

Santos, Angela, Fernandes, Juan, and Mileu, Nelson

Subjects

TSUNAMI warning systems, RISK assessment, CIVILIAN evacuation, TSUNAMIS, CITIES & towns

Abstract

Portugal has had several large tsunamis in the past, yet Oeiras municipality has not implemented mitigation strategies and awareness to the general public, to the authors' knowledge. In addition, Oeiras has 10 beaches that are very popular among residents and tourists, who can become at high risk of a potential tsunami if they do not evacuate from the low ground areas on time. Thus, the tsunami numerical model of the 1755 event was carried out to calculate the inundation, complemented with a field survey, in order to assess the tsunami evacuation conditions of the beaches. The results show the tsunami hits Oeiras municipality 26 to 36 min after the earthquake, inundating all the beaches. The local tsunami hazard classification is Low on 3 beaches, Moderate on 1 beach, High on 5 beaches, and Critical on 1 beach. In addition, there are no tsunami evacuation signs to guide the people to move to higher ground. Therefore, it is important to conduct mitigation strategies to avoid and reduce fatalities in a future tsunami. [ABSTRACT FROM AUTHOR]

Published

2022

20. The Risk Mapping of Coastal Flooding Areas Due to Tsunami Wave Run-Up Using DAS Model and its Impact on Nekor Bay (Morocco).

Author

Taher, Morad, Mourabit, Touafik, El Talibi, Hajar, Etebaai, Issam, Bourjila, Abdelhak, Errahmouni, Ali, and Lamgharbaj, Mastapha

Subjects

TSUNAMIS, RISK assessment, FLOODS, COASTAL ecology, GEOGRAPHIC information systems, SIMULATION methods & models

Abstract

The Al-Hoceima region is threatened by tsunami hazard because of its location in the coastal area of the Mediterranean Sea, besides the shallow seismically active region south of the Alboran Sea. Therefore, the current study presents a novel model to map coastal flooding potential zones due to tsunami wave run-up in Nekor bay using three natural parameters (distance from coastline, altitude and slope) in a geographic information system (GIS) environment. Furthermore, the coastal flooding simulation using 4 scénarios (1, 2, 3, 4m) based on the run-up elevation according to tsunami wave elevation (TWE) literature of the study area is used to confirm the DAS model result, and to estimate the potential impacts. The result of the DAS model revealed that 1 km from the coast to the Nekor plain is the most exposed to the impact of tsunamis generated south of the Alboran Sea. The coastal flooding simulation confirmed the DAS result, and the damage estimation of the urban area and the agriculture was respectively 2 and 98% for run-up 1 m, 3% and 97% for run-up 2m, 4% and 96% for run-up 3m, and for the worst case scenario of 4 m was 3% and 97%. Therefore, the results obtained show that the major potential impact of coastal flooding in Nekor plain is the salinization of agricultural land. Finally, we propose a sustainable solution utilizing a controlled forest along the coast to reduce future tsunami impacts on Nekor bay. [ABSTRACT FROM AUTHOR]

Published

2022

21. MITIGATION OF THE ADVERSE IMPACT OF TSUNAMI HAZARDS ASSISTED BY GEOGRAPHIC INFORMATION SYSTEM: STUDY IN MUNJUNGAN COASTAL-TRENGGALEK - INDONESIA.

Author

Prasetyo, Ketut and Sriutami, Wiwik

Subjects

TSUNAMIS, HAZARD mitigation, GEOGRAPHIC information systems, TSUNAMI hazard zones, ROAD maps, PLATE tectonics, PUBLIC opinion

Abstract

Coastal areas of Indonesia that are close to tectonic plates are vulnerable to earthquakes and generated tsunamis. The Munjungan Coast South of East Java-Indonesia is such a vulnerable tsunami area. This coastal area, besides being close to tectonic plate boundaries, has the shape of an open bay which makes it particularly vulnerable to tsunami impacts and, therefore, in need of strict disaster mitigation measures. Assisted Geographic Information System (GIS) applications with map overlay techniques and by the Arc View 3.3 software program can help in the taking of measures that can reduce the impact of tsunami hazards. The processed product of the GIS methodology in the form of a tsunami hazard zoning map, as well as designated evacuation route maps, can be helpful tools in tsunami impact mitigation, when a significant and potentially tsunamigenic earthquake occurs. The present study used a survey method and area sampling to obtain a better understanding of the public’s perceptions and attitudes in responding more effectively to the potential of tsunami disasters. Based on the interpretation of the zoning map for the classification of disasterprone areas and route maps for evacuation, four villages were identified as being more prone to tsunami disasters. The condition of the population in these four disaster-prone villages, despite their higher level of knowledge about tsunamis, was not followed by their perceptions and proper attitudes towards mitigating the potential danger. People on the coast of Munjungan did not appear to be particularly concerned about the tsunami hazard. [ABSTRACT FROM AUTHOR]

Published

2022

22. Tsunami Alert Efficiency.

Author

Yahav, Amir and Salamon, Amos

Subjects

*TSUNAMIS, *PREPAREDNESS, *EARTHQUAKES

Abstract

Definition: "Tsunami Alert Efficiency" is the rapid, accurate and reliable conduct of tsunami warning messaging, from the detection of potential tsunamigenic earthquakes to dissemination to all people under threat, and the successful survival of every person at risk on the basis of prior awareness and preparedness. [ABSTRACT FROM AUTHOR]

Published

2022

23. Development of a Practical Evaluation Method for Tsunami Debris and Its Accumulation.

Author

Imai, Kentaro, Hashimoto, Takashi, Mitobe, Yuta, Masuta, Tatsuo, Takahashi, Narumi, and Obayashi, Ryoko

Subjects

TSUNAMIS, TSUNAMI warning systems, EVALUATION methodology, NUMERICAL analysis

Abstract

Tsunami-related fires may occur in the inundation area during a huge tsunami disaster, and woody debris produced by the tsunami can cause the fires to spread. To establish a practical method for evaluating tsunami-related fire predictions, we previously developed a method for evaluating the tsunami debris thickness distribution that uses tsunami computation results and static parameters for tsunami numerical analysis. We then used this evaluation method to successfully reproduce the tsunami debris accumulation trend. We then developed an empirical building fragility function that relates the production of debris not only to inundation depth but also to the topographic gradient and the proportion of robust buildings. Using these empirical evaluation models, along with conventional tsunami numerical analysis data, we carried out a practical tsunami debris prediction for Owase City, Mie Prefecture, a potential disaster area for a Nankai Trough mega-earthquake. This prediction analysis method can reveal hazards which go undetected by a conventional tsunami inundation analysis. These results indicate that it is insufficient to characterize the tsunami hazard by inundation area and inundation depth alone when predicting the hazard of a huge tsunami; moreover, more practically, it is necessary to predict the hazard based on the effect of tsunami debris. [ABSTRACT FROM AUTHOR]

Published

2022

24. Risk assessment at Puerto Vallarta due to a local tsunami.

Author

Trejo-Gómez, Elizabeth and Núñez-Cornú, Francisco Javier

Subjects

TSUNAMIS, TSUNAMI warning systems, EARTHQUAKE aftershocks, RISK assessment, EARTHQUAKES

Abstract

The Jalisco region in western Mexico is one of the most seismically active in the country. The city of Puerto Vallarta is located at Bahía de Banderas on the northern coast of Jalisco. Currently there exists a Seismic Gap in the Northern coast of Jalisco (Vallarta Gap). Historically seismogenic tsunamis have affected the coast of Jalisco. In this work, we assess the risk due to a local tsunami in the city of Puerto Vallarta as a function of the interaction between hazard and vulnerability. We model the tsunami hazard, generation and propagation, using the initial conditions for a great earthquake (Mw ≥ 8.0) similar to those that occurred in 1787 at Oaxaca and in 1995 at Tenacatita Bay, Jalisco. Vulnerability is estimated with available data for the years 2010–2015 with sociodemographic variables and the location of government, commercial or cultural facilities. The area with the highest vulnerability and risk is between the valleys of the Ameca and Pitillal Rivers, extending to a distance greater than 5.1 km from the coastline and affecting an area of 30.55 km2. This study does not consider the direct damage caused by the tsunamigenic earthquake and aftershocks; it assumes that critical buildings in the region, mostly hotels, would not collapse after the earthquake and could serve as a refuge for its users. The first (It) tsunami wave arrives to Puerto Vallarta (Cuale) 19 min after the earthquake with a height (Hi) of 3.7 m; the run-up (At) arrives 74 min after earthquake with a height (Hr) of 5.6 m. [ABSTRACT FROM AUTHOR]

Published

2022

25. Technique of local probabilistic tsunami zonation for near-field seismic sources applied to the Bechevinskaya Cove (the Kamchatka Peninsula).

Author

Chubarov, L. B., Kikhtenko, V. A., Lander, A. V., Gusev, O. I., Beisel, S. A., and Pinegina, T. K.

Subjects

TSUNAMI warning systems, TSUNAMIS, PENINSULAS, RISK assessment

Abstract

Currently, the most popular approach for assessing the tsunami hazard on a coast is the PTHA (Probabilistic Tsunami Hazard Assessment). In this preliminary study, we develop one of the variants of the SPTHA (Seismic PTHA) method, adapted to solving local tsunami zonation problems for near-field sources. The approach is applied to assessing the tsunami hazard of the Bechevinskaya Cove located on the eastern coast of the Kamchatka Peninsula in the northern part of Avachinsky Bay. We propose the method, algorithms and results of probabilistic assessment of the cove's tsunami hazard in order to determine the safest water areas, in which the values of the intensity measures (IMs) of tsunami will not exceed the specified threshold values with the given Average Return Periods (ARPs). The method includes analysis of seismotectonics of the region, construction of a catalog of model tsunamigenic earthquakes, determination of their statistical characteristics, scenario numerical modeling of the dynamics of tsunami waves, calculations of the values of IMs that can be exceeded with the given annual rates (ARs), namely, on average 1 time in 100, 500, 1000 years. Spatial distributions of the maximum wave heights and maximum velocities are provided for the ARs. Three configurations of the water area are considered, including the possibility of constructing protective structures, and conclusions are drawn about their influence on the tsunami hazard assessments in the cove. [ABSTRACT FROM AUTHOR]

Published

2022

26. A first estimation of tsunami hazard of the Pacific coast of Costa Rica from local and distant seismogenic sources.

Author

Chacon-Barrantes, Silvia and Arozarena-Llopis, Isabel

Subjects

*TSUNAMI warning systems, *TSUNAMIS, *CONTINENTAL slopes, *CONTINENTAL shelf, *ENERGY dissipation, *COASTS

Abstract

Costa Rica has been affected by several local and distant tsunamis in the past, but the historical information is scarce and incomplete. Its Pacific coast stretches for over a thousand kilometers, and tsunami hazard has never been evaluated for its full extent. Numerical modeling of tsunami propagation and inundation is a useful tool to assess tsunami hazard, particularly in cases with limited historical information available. Here, we perform a first estimation of tsunami hazard for the Pacific coast of Costa Rica from seismogenic sources, by numerical propagation of 57 local and distant tsunamis to a depth of 20 m. The results of our study identified tsunami sources that are particularly threatening for Costa Rica and determined locations with higher tsunami hazard. For the analysis, the Pacific coast of Costa Rica was divided into segments and subsegments based on differences in continental slope morphology. Subsegments with higher tsunami heights were Southwest Nicoya Peninsula and West Osa Peninsula, and in a lesser extent North Guanacaste, North Nicoya Peninsula, and Central Pacific. Regions with long and gentle slopes and narrow continental shelf were affected by higher tsunami waves, due to more efficient tsunami energy transmission to the shelf and reduced energy loss while traveling through a narrow shelf. On the opposite, steeper continental slopes reflected most of the tsunami energy, causing smaller tsunami heights nearshore, regardless of the shelf width. Nevertheless, other effects played a major role, like curved coastlines that focused tsunami energy, wave refraction, interference, and trapped edge waves. Distant tsunamis dominated the threat, with tsunamis coming from the Tonga-Kermadec and the Colombia-Ecuador Trenches causing the greatest heights due to directivity, and arrival times of about 15 h and 75 min, respectively. Local tsunamis had short arrival times but a localized impact, mainly at the shoreline in front of the generation region but were also affected by tsunami focusing, wave refraction, and edge waves. Outer rise and Osa sources caused the lowest impact within local sources. These results provide a guide for emergency planners to prioritize coastal locations and tsunami sources for tsunami preparedness actions and warning protocols. [ABSTRACT FROM AUTHOR]

Published

2021

27. Social vulnerability to seismic-tsunami hazards in district Gwadar, Balochistan, Pakistan.

Author

Mengal, Amanullah, Goda, Katsuichiro, Ashraf, Muhammad, and Murtaza, Ghulam

Subjects

TSUNAMIS, TSUNAMI warning systems, EMERGENCY management, EARTHQUAKE magnitude, PRINCIPAL components analysis, SUBDUCTION zones, HAZARDS

Abstract

Social vulnerability illuminates differences in human capacity to prepare for, respond to, and recover from disasters. It varies over space and time and among social groups, largely due to variations in socioeconomic and demographic features. The Makran Subduction Zone is one of the known active seismic sources that can generate devastating shaking and tsunami disasters in District Gwadar, Pakistan, such as a large earthquake of moment magnitude 8.1 in 1945. This study presents the first social vulnerability index study for District Gwadar in relation to imminent earthquake-tsunami hazards and shows how SoVI concepts and indicators are adopted. SoVI follows a place-based framework that was originally adopted in developing social vulnerability index for the USA. To assess social vulnerability to earthquakes and tsunamis in Gwadar, we evaluate a social vulnerability index at village level. Using a principal component analysis, 16 village-level indicators are condensed to five factors that explain 64.2% of the variance in the data. Although different factors contribute to the social vulnerability in each village, the overall results confirm the social and economic disparities among villages and reflect differential vulnerability to natural hazards at local to regional scales. Finally, a map of social vulnerability index is compared with seismic-tsunami hazard maps to identify the communities living in risky zones. The approaches and results presented in this study will help emergency managers to identify community sub-groups that are more susceptible to disaster risks and to develop effective risk reduction strategies that are tailored to local conditions. [ABSTRACT FROM AUTHOR]

Published

2021

28. Risk estimation of the disaster waste generated by both ground motion and tsunami due to the anticipated Nankai Trough earthquake.

Author

Ishibashi, Hiroki, Akiyama, Mitsuyoshi, Kojima, Takayuki, Aoki, Koki, Koshimura, Shunichi, and Frangopol, Dan M.

Subjects

TSUNAMI warning systems, SENDAI Earthquake, Japan, 2011, TSUNAMI hazard zones, EARTHQUAKE hazard analysis, TSUNAMIS

Abstract

The amount of disaster waste is one of the most important performance indicators in quantifying the resilience of a community. In fact, disaster waste can have significant negative impacts on the environment in affected regions and hinder the postdisaster recovery process. Appropriate disaster waste management should be developed in Japan before the occurrence of the Nankai Trough earthquake. It is expected that the seismic and tsunami intensities caused by the anticipated Nankai Trough earthquake will be substantially larger than those caused by the 2011 Great East Japan earthquake. In this paper, a risk‐based methodology is presented for estimating the amount of disaster waste generated by both the ground motions and the tsunami due to the anticipated Nankai Trough earthquake. First, Monte Carlo simulation‐based probabilistic hazard analyses are performed to obtain seismic and tsunami hazard curves considering the uncertainty associated with fault movement along the Nankai Trough. Structural damage data associated with past earthquakes are used to develop seismic and tsunami fragility curves. The amount of disaster waste generated from a single structure is defined as the generation unit and is determined based on past disasters. Finally, with the aid of a geographic information system, the risk of disaster waste can be estimated using the hazard and fragility curves and the generation units. As an illustrative example, the risk curves and expected values associated with disaster waste in Mie Prefecture, Japan, are estimated based on the proposed framework. [ABSTRACT FROM AUTHOR]

Published

2021

29. Life-Cycle Performance Assessment of Aging Bridges Subjected to Tsunami Hazards.

Author

Xu, Ji-Gang, Feng, De-Cheng, and Wu, Gang

Subjects

TSUNAMI damage, TSUNAMI warning systems, TSUNAMIS, FLOW velocity, LOGNORMAL distribution, DETERIORATION of materials, REINFORCED concrete

Abstract

Coastal reinforced concrete (RC) bridges have the potential to be subjected to tsunami hazards within their service life. On the other hand, the time-dependent chloride-induced corrosion will degrade the performance of the bridges. Few efforts have been made to investigate the life-cycle performance of deteriorating RC bridges subjected to tsunami hazards. In this paper, the time-dependent collapse fragility analysis is conducted to investigate the life-cycle performance of deteriorating RC bridges subjected to tsunami hazards. With corrosion modeling, the time-dependent deterioration of material properties as well as shear capacity deterioration of the columns are considered. Uncertainties from materials are accounted for in developing numerical bridge models. Nonlinear tsunami pushover analysis is used to investigate the bridge damage under tsunami loading. Tsunami collapse failure curves are constructed assuming a lognormal distribution, and the time-dependent tsunami collapse fragility curves can be efficiently calculated with the quadratic model for the median and standard deviation of tsunami intensity, that is, flow velocity. Time-dependent collapse fragility analysis is conducted for a three-span, two-column bent RC bridge. Results indicate that the bridge columns can fail in shear for low inundation depth flow and high corrosion levels. Collapse failure probability of the bridge increases with the flow depth and a clear jump of collapse failure probability for inundation depth from below to above the deck can be observed. The collapse failure probability also increases over time due to corrosion effects. [ABSTRACT FROM AUTHOR]

Published

2021

30. Predicting tsunami-like solitary wave run-up over fringing reefs using the multi-layer perceptron neural network.

Author

Yao, Yu, Yang, Xiaoxiao, Lai, Sai Hin, and Chin, Ren Jie

Subjects

REEFS, TSUNAMI warning systems, TSUNAMIS, CORAL reefs & islands, BOUSSINESQ equations, WATER levels

Abstract

Modeling of tsunami wave interaction with coral reefs to date focuses mainly on the process-based numerical models. In this study, an alternative machine learning technique based on the multi-layer perceptron neural network (MLP-NN) is introduced to predict the tsunami-like solitary wave run-up over fringing reefs. Two hydrodynamic forcings (incident wave height, reef-flat water level) and four reef morphologic features (reef width, fore-reef slope, beach slope, reef roughness) are selected as the input variables and wave run-up on the back-reef beach is assigned as the output variable. A validated numerical model based on the Boussinesq equations is applied to provide a dataset consisting of 4096 runs for MLP-NN training and testing. Results analyses show that the MLP-NN consisting of one hidden layer with ten hidden neurons provides the best predictions for the wave run-up. Subsequently, model performances in view of individual input variables are accessed via an analysis of the percentage errors of the predictions. Finally, a mean impact value analysis is also conducted to evaluate the relative importance of the input variables to the output variable. In general, the adopted MLP-NN has high predictive capability for wave run-up over the reef-lined coasts, and it is an alternative but more efficient tool for potential use in tsunami early warning system or risk assessment projects. [ABSTRACT FROM AUTHOR]

Published

2021

31. Can Modeling the Geologic Record Contribute to Constraining the Tectonic Source of the 1755 CE Great Lisbon Earthquake?

Author

Dourado, F., Costa, P. J. M., La Selle, S., Andrade, C., Silva, A. N., Bosnic, I., and Gelfenbaum, G.

Subjects

*TSUNAMI warning systems, *EARTHQUAKES, *SEDIMENT transport, *TSUNAMIS, *SEISMIC testing, *RISK assessment, *SAND dunes

Abstract

The precise location of the seismic source of 1755 CE Great Lisbon earthquake is still uncertain. The aim of this work is to use an onland sedimentary record in southern Portugal to test and validate seismic sources for the earthquake. To achieve this, tsunami deposit thicknesses from over 150 cores collected at Salgados in southern Portugal were compared to the results of a tsunami sediment transport model (Delft3D‐FLOW) that simulates tsunami propagation, inundation, erosion, and deposition. Five different hypothetical seismic sources were modeled with varying bed roughness coefficients to assess how well they reproduced observed patterns of tsunami deposit thicknesses and dune. Modeled and observed historical tsunami arrival times were also used to test different earthquake sources. Based on these comparisons, three modeled earthquake sources were able to reproduce the observed data, suggesting they should be regarded as somewhat more likely sources for the 1755 earthquake in contrast to four other modeled sources. The fault closest to shore (Marquês de Pombal) yielded the best correlations between model and observations. Plain Language Summary: The precise location of the seismic source of 1755 CE Great Lisbon earthquake is still uncertain. The aim of this work is to use an onland sedimentary record in southern Portugal to test and validate seismic sources for the earthquake. To achieve this, tsunami deposit thicknesses from over 150 cores collected at Salgados in southern Portugal were compared to the results of a tsunami sediment transport model (Delft3D‐FLOW) that simulates tsunami propagation, inundation, erosion, and deposition. Seven different hypothetical seismic sources were modeled with varying bed roughness coefficients to assess how well they reproduced observed patterns of tsunami deposit thicknesses and dune. Modeled and observed historical tsunami arrival times were also used to test different earthquake sources. Based on these comparisons, three modeled earthquake sources were able to reproduce the observed data, suggesting they should be regarded as most likely sources for the 1755 earthquake in contrast to four other modeled sources. The fault closest to shore (Marquês de Pombal) yielded the best correlations between model and observations Key Points: 1755 CE epicenter assessment based in geological data and sediment transport modelingInnovative combination of historical, geological, and modeling dataContribution for hazard assessment in Iberia [ABSTRACT FROM AUTHOR]

Published

2021

32. Framework for estimating the risk and resilience of road networks with bridges and embankments under both seismic and tsunami hazards.

Author

Ishibashi, Hiroki, Akiyama, Mitsuyoshi, Frangopol, Dan M., Koshimura, Shunichi, Kojima, Takayuki, and Nanami, Kengo

Subjects

*TSUNAMI warning systems, *TSUNAMIS, *TSUNAMI damage, *EMBANKMENTS, *SENDAI Earthquake, Japan, 2011, *HAZARD mitigation, *MONTE Carlo method, *SOCIAL impact

Abstract

To develop disaster mitigation measures in coastal regions affected by earthquakes, it is important to consider the effects of both seismic and tsunami hazards on road structures and assess the social impacts associated with the economic loss and reduction in network functionality. In this paper, a risk- and resilience-based assessment framework is established for road networks under both seismic and tsunami hazards. In the proposed methodology, the risk and resilience are quantified by the economic loss and postdisaster functionality of road networks, respectively. Uncertainties associated with estimations of fault movement, hazard intensity and structural vulnerability are considered when estimating the failure probability using Monte Carlo simulation. Moreover, structural vulnerability against tsunamis is estimated considering the effects of ground motion-induced damage on the reduction in tsunami capacity. As an illustrative example, the road networks in two Japanese cities expected to be affected by the anticipated Nankai Trough earthquake, which would cause strong ground motions and a subsequent tsunami, are analyzed. Finally, the retrofitting prioritization for various structures is discussed based on the risk and resilience quantified as performance indicators for social impacts. [ABSTRACT FROM AUTHOR]

Published

2021

33. A new tsunami runup predictor.

Author

Wronna, Martin, Baptista, Maria Ana, and Kânoğlu, Utku

Subjects

TSUNAMIS, TSUNAMI warning systems

Abstract

We introduce a new parameter, tsunami runup predictor (TRP), relating the accelerating phase of the wave to the length of the beach slope over which the wave is travelling. We show the existence of a relationship between the TRP and the runup for different initial waveforms, i.e. leading elevation N-waves (LENs) and leading depression N-waves (LDNs). Then, we use the TRP to estimate tsunami runup for past tsunami events. The comparison of the runup estimates against field data gives promising results. Thus, the TRP provides first-order estimates of tsunami runup once the offshore waveform is known or estimated and, therefore, it could be beneficial to be implemented in tsunami early warning systems. [ABSTRACT FROM AUTHOR]

Published

2021

34. Tsunamis from prospected mass failure on the Marsili submarine volcano flanks and hints for tsunami hazard evaluation.

Author

Gallotti, G., Zaniboni, F., Pagnoni, G., Romagnoli, C., Gamberi, F., Marani, M., and Tinti, S.

Subjects

*TSUNAMI warning systems, *TSUNAMIS, *SUBMARINE volcanoes, *WATER depth, *VOLCANOES, *RESEARCH teams, *SEAMOUNTS

Abstract

The Marsili Seamount (Tyrrhenian Sea, Italy) is the largest submarine volcano in the Mediterranean Sea, located in the middle of the Marsili Basin, facing the Calabrian and Sicilian coasts on its eastern side, and the coasts of Sardinia on the opposite side. It has erupted in historical times, and its summit crest is affected by widespread hydrothermal activity. This study looks at mass failures taking place at different depths on the flanks of the volcano and estimates their associated tsunamigenic potential. Mass failure, tsunami generation, and propagation have been simulated by means of numerical models developed by the Tsunami Research Team of the University of Bologna. In all, we consider five cases. Of these, three scenarios, one regarding a very small detachment and two medium-sized ones (between 2 and 3 km3 failure volume), have been suggested as possible failure occurrences in the published literature on a morphological basis and involve the north-eastern and north-western sectors of the volcano. The two additional cases, one medium-sized and one extreme, intended as a possible worst-case scenario (volume 17.6 km3), affecting the eastern flank. Results indicate that small-volume failures are not able to produce significant tsunamis; medium-size failures can produce tsunamis which dangerously affect the coasts if their detachment occurs in shallow water, i.e., involves the volcano crest; and extreme volume failures have the potential to create disastrous tsunamis. In all the simulations, tsunami waves appear to reach the Aeolian Islands in around 10 min and the coasts of Calabria and Sicily in 20 min. This study highlights that there is a potential for dangerous tsunamis generation from collapses of the Marsili volcano and as a consequence a need to intensify research on its status and stability conditions. More broadly, this investigation should also be extended to the other volcanic seamounts of the Tyrrhenian Sea, since their eruptive style, evolution, and tsunamigenic potential are still poorly known. [ABSTRACT FROM AUTHOR]

Published

2021

35. Seiche Effects in Lake Tekapo, New Zealand, in an Mw8.2 Alpine Fault Earthquake.

Author

Wang, Xiaoming, Holden, Caroline, Power, William, Liu, Yaoru, and Mountjoy, Joshu

Subjects

*SEICHES, *LAKES, *EARTHQUAKES, *TSUNAMIS, *OSCILLATIONS

Abstract

This study investigates the potential for seismic seiches in Lake Tekapo, New Zealand, triggered by ground shaking from an Mw8.2 Alpine Fault earthquake. Synthetic ground motions are used as a forcing boundary to drive lake water motions by further developing a tsunami simulation model—COMCOT—and coupling it with earthquake simulation model outputs. Our modelling results reveal that lake water oscillations are mobilised immediately by the ground movement and further amplified by cross-lake seiches. Amplitudes of lake oscillations can reach up to 4.0 m in the lake's narrow southern arm, over 1.0 m along the shore of Lake Tekapo township, and about 1.5–2.5 m along many other parts of the lake shore. Large-amplitude water oscillations quickly attenuate in the first 5–10 min after the earthquake due to their relatively short periods, while long-period oscillations continue for a long time, albeit with much smaller amplitudes. Spectral analysis clearly reveals that the ground motions trigger both fundamental and higher modes in the lake whose oscillation periods are consistent with theoretical estimates. We find that large-amplitude lake water oscillations are better correlated with low-frequency, less energetic ground motion content than with high-frequency large-amplitude ground motions. Ground motion-triggered lake oscillations are large enough to pose potential threat to tourists, residents, boats and infrastructure both in the lake water and onshore near the waterfront. In contrast, vertical co-seismic displacements in the lake area, the conventional mechanism for tsunami generation, are too small to trigger tsunami waves of concern. [ABSTRACT FROM AUTHOR]

Published

2020

36. Tsunami hazard in the Caribbean coast of Honduras due to large earthquakes occurred along the Cayman Trough at the northwest boundary of Caribbean plate.

Author

Tanioka, Yuichiro, Cabrera, Amilcar Geovanny, Arguello, Greyving Jose, and Yamanaka, Yusuke

Subjects

*TSUNAMI warning systems, *TSUNAMIS, *EARTHQUAKES, *TSUNAMI hazard zones, *FAULT zones, *OCEAN bottom, *COASTS

Abstract

In 2018, a large earthquake (Mw7.6) occurred in the Swan Island Fault zone at the northwest boundary of the Caribbean plate. This earthquake generated a small tsunami of 20 cm. However, Puerto Cortes in Honduras is located close to the Swan Island Fault zone. Evaluation of tsunami hazard at Puerto Cortes due to large earthquakes along the fault zone is important. We first estimated the fault parameters of the 2018 Swan Island earthquake using W-phase inversion technique. Then, the moment magnitude of 7.6, the fault length of 134 km, the fault width of 24 km, and the slip amount of 5.1 m were estimated. In addition to those estimates, a small fault dimension of the earthquake, 40 km × 20 km, with a slip amount of 20.8 m was considered. Those two fault models were used to compute tsunami inundation at Puerto Cortes. The tsunami computed from the small fault inundated a large area in Puerto Cortes including the port area. The effect of co-seismic horizontal displacement of ocean floor also enhanced the tsunami inundation at Puerto Cortes. Those results indicate that preparation for future tsunami hazard in Puerto Cortes is important although no significant tsunami was generated historically. [ABSTRACT FROM AUTHOR]

Published

2020

37. The 1674 Ambon Tsunami: Extreme Run-Up Caused by an Earthquake-Triggered Landslide.

Author

Pranantyo, Ignatius Ryan and Cummins, Phil R.

Subjects

*TSUNAMIS, *TSUNAMI hazard zones, *SENDAI Earthquake, Japan, 2011, *LANDSLIDES, *LANDSCAPE changes

Abstract

We present an analysis of the oldest detailed account of tsunami run-up in Indonesia, that of the 1674 Ambon tsunami (Rumphius in Waerachtigh Verhael van de Schuckelijcke Aerdbebinge, BATAVIA, Dutch East Indies, 1675). At 100 m this is the largest run-up height ever documented in Indonesia, and with over 2300 fatalities even in 1674, it ranks as one of Indonesia's most deadly tsunami disasters. We consider the plausible sources of earthquakes near Ambon that could generate a large, destructive tsunami, including the Seram Megathrust, the South Seram Thrust, and faults local to Ambon. We conclude that the only explanation for the extreme run-up observed on the north coast of Amon is a tsunami generated by an earthquake-triggered coastal landslide. We use a two-layer tsunami model to show that a submarine landslide, with an approximate volume of 1 km3, offshore the area on Ambon's northern coast, between Seith and Hila, where dramatic changes in coastal landscape were observed can explain the observed tsunami run-up along the coast. Thus, the 1674 Ambon tsunami adds weight to the evidence from recent tsunamis, including the 1992 Flores, 2018 Palu and Sunda Strait tsunamis, that landslides are an important source of tsunami hazard in Indonesia. [ABSTRACT FROM AUTHOR]

Published

2020

38. Global Occurrence of Large Tsunamis and Tsunami-like Waves Within the Last 120 years (1900–2019).

Author

Gusiakov, Viacheslav K.

Subjects

*TSUNAMIS, *TSUNAMI damage, *TERRITORIAL waters, *FJORDS, *TWENTIETH century

Abstract

The run-up catalogs of two global tsunami databases maintained by the NCEI/WDC NOAA and NTL/ICMMG SD RAS are examined to compile the list of annual maximum runups observed or measured in the oceanic, marine and inland basins during the last 120 years (from 1900 to 2019). All the retrieved annual maximum runups were divided into four groups according to four main types of tsunami sources (seismogenic, landslide-generated, volcanic, and meteorological). Their distribution over the type of sources shows that of the 120 maximum runups only 78 (65%) resulted from seismogenic sources, while the remaining 42 runups were divided between landslide-generated (19%), volcanic (8%), and meteorological (7.5%) sources. The analysis of geographical distribution of source locations demonstrates that tsunamis are not exclusively a marine hazard—over 15% of all maximum runups were observed in coastal and inland water basins (narrow bays, fiords, lakes, and rivers). Temporal distribution of the collected runups shows that annual occurrence of large tsunamis was more or less stable throughout the twentieth century and only demonstrates some increase during the last 27 years (since 1992) when the practice of post-event surveys of all damaging tsunamis was implemented. This paper also outlines the existing problems with data compilation, cataloguing, and distribution, and discusses incompleteness of runup and wave-form data for a considerable number of non-damaging tsunamis, even those resulting from the strong (magnitude higher than 7.5) submarine earthquakes. [ABSTRACT FROM AUTHOR]

Published

2020

39. Probabilistic Tsunami Hazard Assessment for Local and Regional Seismic Sources Along the Pacific Coast of Central America with Emphasis on the Role of Selected Uncertainties.

Author

Zamora, Natalia and Babeyko, Andrey Y.

Subjects

*TSUNAMI hazard zones, *TSUNAMIS, *EARTHQUAKE hazard analysis, *SUBDUCTION zones, *EARTHQUAKE zones, *PROPORTIONAL hazards models

Abstract

Historical data indicate that the Middle America subduction zone represents the primary tsunamigenic source that affects the Central American coastal areas. In recent years, the tsunami potential in the region has mainly been assessed using maximum credible earthquakes or historical events showing moderate tsunami potential. However, such deterministic scenarios are not provided with their adequate probability of occurrence. In this study, earthquake rates have been combined with tsunami numerical modeling in order to assess probabilistic tsunami hazard posed by local and regional seismic sources. The common conceptual framework for the probabilistic seismic hazard assessment has been adapted to estimate the probabilities of exceeding certain tsunami amplitudes along the Central American Pacific coast. The study area encompasses seismic sources related to the Central America, Colombia and Ecuador subduction zones. In addition to the classical subduction inter-plate events, this study also incorporates sources at the outer rise, within the Caribbean crust as well as intra-slab sources. The study yields conclusive remarks showing that the highest hazard is posed to northwestern Costa Rica, El Salvador and the Nicaraguan coast, southern Colombia and northern Ecuador. In most of the region it is 50 to 80% likely that the tsunami heights will exceed 2 m for the 500 year time exposure (T). The lowest hazard appears to be in the inner part of the Fonseca Gulf, Honduras. We also show the large dependence of PTHA on model assumptions. While the approach taken in this study represents a thorough step forward in tsunami hazard assessment in the region, we also highlight that the integration of all possible uncertainties will be necessary to generate rigorous hazard models required for risk planning. [ABSTRACT FROM AUTHOR]

Published

2020

40. Tsunami Potential of Moderate Earthquakes: The July 1, 2009 Earthquake (Mw 6.45) and its Associated Local Tsunami in the Hellenic Arc.

Author

Bocchini, Gian Maria, Novikova, T., Papadopoulos, G. A., Agalos, A., Mouzakiotis, E., Karastathis, V., and Voulgaris, N.

Subjects

*TSUNAMIS, *TSUNAMI warning systems, *EARTHQUAKES, *TSUNAMI hazard zones, *SEISMIC event location

Abstract

On July 1, 2009, a Mw 6.45 earthquake ruptured south of Crete Island (Greece) along the Hellenic Arc triggering a local tsunami. Eyewitness reported the tsunami from Myrtos and Arvi (south-eastern Crete) and from the north of Chrisi Islet, located to the southeast of Crete. The earthquake occurred offshore, about 80 km south of Crete, where routine earthquake locations are poor. The hypocentre is relocated using a 2-D velocity model and several local 1-D velocity models. Epicentral locations obtained by using the different velocity models show very minor variations. Instead, relocated hypocentres can be grouped into two sets of solutions: (1) those with a shallower depth (depth < 12 km) obtained with the 2-D velocity model and the 1-D velocity models having a shallower Moho at less than 30 km, and (2) those with a larger depth (depth of 28 and 40 km) obtained with the velocity models having a Moho at about 40 km. Shallower hypocentres are more consistent with the tsunamigenic nature of the earthquake as also supported by tsunami numerical simulations. In fact, shallow sources (depths < 12 km) are capable of generating tsunami waves, while it is not the case for deeper sources (depth > 25 km) either in the upper-plate or along the plate interface. Models accounting for either homogeneous or heterogeneous slip on the causative fault are tested, with the heterogeneous one better reproducing the observations in terms of number of tsunami waves reaching the shoreline and duration of the sea disturbance. The short travel time, about 10 min, of the first tsunami arrival at the southern coast of Crete represents a big challenge for tsunami early warning systems operating in the area. [ABSTRACT FROM AUTHOR]

Published

2020

41. Numerical modelling of coastal inundation from Cascadia Subduction Zone tsunamis and implications for coastal communities on western Vancouver Island, Canada.

Author

Takabatake, Tomoyuki, St-Germain, Philippe, Nistor, Ioan, Stolle, Jacob, and Shibayama, Tomoya

Subjects

TSUNAMI hazard zones, TSUNAMIS, SUBDUCTION zones, FLOODS, SHALLOW-water equations, FLOW velocity, EARTHQUAKE zones

Abstract

In the present study, numerical simulations were conducted to estimate the spatio-temporal characteristics of tsunami inundation for municipalities on Vancouver Island, Canada, as a result of various potential Cascadia Subduction Zone earthquake deterministic scenarios. By varying the earthquake magnitude and associated slip distance, the influence of these parameters on the tsunami wave propagation, inundation, and the possible damage on infrastructure and buildings was investigated. A numerical tsunami inundation model based on nonlinear shallow water equations was constructed using publically available bathymetric and topographic data and applied to three study areas: the City of Port Alberni, the District of Ucluelet, and the District of Tofino. The numerical results obtained in this study show that the maximum tsunami inundation depth and spatial extent of inundation are sensitive to the earthquake magnitude, whereas the tsunami arrival time is not. For the worst-case earthquake scenario investigated (MW 9.3), all of the three study areas were extensively inundated. Results of tsunami wave amplitude and overland inundation depth, flow velocity, hydrodynamic force, and depth–velocity product are analysed in detail to assess the impacts of the tsunami on inland buildings. The potential damage was estimated with previously proposed fragility curves for wood, reinforced concrete, and steel frame buildings. In conjunction with a site reconnaissance visit by the authors for better understanding the general characteristics of these areas, model results suggest that significant damage to buildings would occur, especially to wooden constructions, with considerable risk of loss of human life. [ABSTRACT FROM AUTHOR]

Published

2019

42. Multi-Data-Type Source Estimation for the 1992 Flores Earthquake and Tsunami.

Author

Pranantyo, Ignatius Ryan and Cummins, Phil R.

Subjects

*TSUNAMIS, *TSUNAMI hazard zones, *EARTHQUAKES, *LAND subsidence, *THRUST, *COASTS, *TIDES

Abstract

We revisit the source of the 1992 Flores earthquake and tsunami using finite-fault inversion. We simultaneously invert teleseismic body and surface waves together with coseismic uplift/subsidence datasets. We then verify the inverted source against tsunami run-up heights along the northern coast of Flores Island and the only tide gauge recording of the tsunami. Our preferred source model provides a good fit to all the datasets, whereas previous models only explained a subset of the available data. We show that the fault geometry implies segmentation of the back-arc thrust system in the eastern Sunda Arc. [ABSTRACT FROM AUTHOR]

Published

2019

43. Tsunami hazard from submarine landslides: scenario-based assessment in the Ulleung Basin, East Sea (Japan Sea).

Author

Urgeles, Roger, Bahk, Jang-Jun, Lee, Sang-Hoon, Horozal, Senay, Cukur, Deniz, Kim, Seong-Pil, Kim, Gil-Young, Jeong, Sueng-Won, and Um, In-Kwon

Subjects

*LANDSLIDES, *TSUNAMI hazard zones, *TSUNAMIS, *CONTINENTAL slopes, *EPISTEMIC uncertainty, *SEAS, *CONTINENTAL margins

Abstract

In this study we use a scenario-based approach to highlight potential tsunami hazard from actual Late Pleistocene submarine landslides in the Ulleung Basin: two submarine landslides on the western slope of the Ulleung Basin, north and south of the Hupo Bank (2.53 and 1.12 km3 respectively) and a landslide (15.1 km3) on the continental slope south of the Ulleung Basin. The simulations attempt to highlight the consequences, should one of these events occur at Present. Results of the simulations indicate potential local hazard zones with very local waves < 2 m high in the Korean coast of the East Sea that could result from midsized landslides, not exceeding 3 km3 on the western slope of the basin. Time available for early warning since onset of these events is between 15–30 minutes. On the other hand, the continental margin south of the Ulleung Basin is an area where landslide tsunamis with significant hazard potential could originate. New landslides of similar size to those of the Late Pleistocene could produce tsunami waves > 3 m in the stretch of coastline from Ulsan in the south to Uljin in the north. The timing available for early warning from landslide tsunamis originating in this area is 15–30 minutes along the affected section of the shoreline. We also suggest a Probabilistic Tsunami Hazard Assessment (PTHA) for comprehensive assessments of the Korean coast of the East Sea. PTHA accounts for uncertainties in location, release mechanisms, evolution, and return periods of submarine landslides as well as epistemic uncertainty. However, to constrain these uncertainties detailed information on source areas, recurrence period and dynamics of submarine landslides is necessary and calls for additional data collection and further studies. [ABSTRACT FROM AUTHOR]

Published

2019

44. COMPARATIVE STUDY REGARDING THE RISK PERCEPTION OF TSUNAMIS FROM EFORIE NORD (ROMANIA) AND NICE (FRANCE) COMMUNITIES.

Author

CONSTANTIN, Angela Petruţa, MOLDOVAN, Iren-Adelina, PARTHENIU, Raluca, LAVIGNE, Franck, GRANCHER, Delphine, and IONESCU, Constantin

Subjects

TSUNAMIS, EMERGENCY management, NATURAL disasters

Abstract

The goal of this paper is to present a comparative study of the people perception from two different sites from Romania and France, regarding the tsunami risk in the Black and Mediterranean Seas communities. These two surveys over residents' and tourists' perception and preparedness of tsunami hazard were carried out for both towns, Eforie Nord(Romania) and Nice (France), in the frame of the ASTARTE project - „Assessment, Strategy And Risk reduction for Tsunamis in Europe" (EC Programme FP7).Data were collected by tsunami questionnaire developed in the project and translated in Romanian and French languages, and the questions are referring to: interviewee's relation to Eforie Nord and Nice sites, information about interviewed people, tsunami hazard knowledge/risk perception, evacuation issue, awareness of the existing warning system, information, and communication. A total of 256 subjects participated at surveys from both sites situated along coasts of Black and Mediterranean seas.The results of the survey showed a moderate level of tsunami preparedness and perception of people living in, working in, or visiting Eforie Nord and Nice sites, our respondents mentioned the tsunami as third rank in both sites, coming after (i.e. local population, or tourists), earthquakes and sea withdrawal are cited as tsunami warning signs by 62% and 60% of the respondents from Eforie Nord and by 30% and 31% of the respondents from Nice, respectively.When considering a future tsunami being generated in Eforie Nord, 36,3% of the respondents think that the place could be affected by a tsunami and the waves could reach more than 2-5 meters (heights cited by approx. 14% of respondents) or even more than 5-10 meters (values cited by 15% of interviewed people). Regarding the Nice site, 78% of the respondents think that the place could be affected by a tsunami in the future. With such a negative perception of tsunamis, it is not surprising that more than 29% of the respondents from Nice site expect waves of more than 10 m high. This study provided evidence that tsunamis recently occurred in the world have a significant impact on people's preparedness and perception. [ABSTRACT FROM AUTHOR]

Published

2018

45. Tsunami Hazard Assessment of Coastal South Africa Based on Mega-Earthquakes of Remote Subduction Zones.

Author

Kijko, Andrzej, Smit, Ansie, Papadopoulos, Gerassimos A., and Novikova, Tatyana

Subjects

*TSUNAMIS, *TSUNAMI hazard zones, *COASTS, *SUBDUCTION zones, *COASTAL zone management

Abstract

After the mega-earthquakes and concomitant devastating tsunamis in Sumatra (2004) and Japan (2011), we launched an investigation into the potential risk of tsunami hazard to the coastal cities of South Africa. This paper presents the analysis of the seismic hazard of seismogenic sources that could potentially generate tsunamis, as well as the analysis of the tsunami hazard to coastal areas of South Africa. The subduction zones of Makran, South Sandwich Island, Sumatra, and the Andaman Islands were identified as possible sources of mega-earthquakes and tsunamis that could affect the African coast. Numerical tsunami simulations were used to investigate the realistic and worst-case scenarios that could be generated by these subduction zones. The simulated tsunami amplitudes and run-up heights calculated for the coastal cities of Cape Town, Durban, and Port Elizabeth are relatively small and therefore pose no real risk to the South African coast. However, only distant tsunamigenic sources were considered and the results should therefore be viewed as preliminary. [ABSTRACT FROM AUTHOR]

Published

2018

46. Scenarios of Earthquake-Generated Tsunamis for the Italian Coast of the Adriatic Sea

Author

Tiberti, Mara Monica, Lorito, Stefano, Basili, Roberto, Kastelic, Vanja, Piatanesi, Alessio, Valensise, Gianluca, Cummins, Phil R., editor, Satake, Kenji, editor, and Kong, Laura S. L., editor

Published

2009

47. Análisis de sensibilidad de la fuente de generación y de las condiciones de contorno en la evaluación de la inundación por tsunami en zonas costeras

Author

Sánchez Jiménez, Cristina, Aniel-Quiroga Zorrilla, Iñigo, González Rodríguez, Mauricio, and Universidad de Cantabria

Subjects

Parámetros fuente sismo tectónica de Okada, Tsunami inundation, Tsunami numerical modeling, Inundation sensitivity, Mapas de inundación, Modelación numérica de tsunamis, Tsunamis, Inundation maps, Okada parameters, Inundación por tsunami, Tsunami hazard, Sensibilidad de inundación, Peligrosidad por tsunamis

Abstract

RESUMEN: Los desastres naturales son definidos por la Agencia Europea de Medio Ambiente (EEA) como aquellos cambios violentos, súbitos y destructivos en el entorno cuya causa no es debido a la actividad humana, sino por fenómenos naturales. El estudio de los tsunamis ha sido ampliamente abordado en las últimas décadas debido a que se presentan como eventos naturales relativamente poco frecuentes, pero con las mayores tasas de mortalidad. La posibilidad de que se origine un maremoto que afecte las costas españolas es real y su ocurrencia es imprevisible. Es por tanto necesaria una gestión adecuada en los ámbitos de prevención y preparación. La importancia de estudios de la peligrosidad por tsunamis radica en que dan claridad respecto al grado de peligro al cual están expuestos los ciudadanos. Esta situación realza la necesidad de realizar estudios de riego de tsunamis, generar sistemas de alerta temprana y definir, tomar y fomentar estrategias de mitigación del impacto de tsunamis a escala local o regional, con el fin de proteger a la población expuesta a estos posibles eventos. Es común que el análisis de la peligrosidad por tsunami se realice a través de modelaciones numéricas de eventos históricos o potenciales. En estas simulaciones es necesario caracterizar el terremoto generador del tsunami, lo cual se realiza a través de la definición de una serie de parámetros cuya variabilidad afecta al resultado de la simulación y al impacto sobre las zonas inundables. En general, se acepta el modelo de Okada (1985) como un método adecuado para representar el desplazamiento de la superficie libre que genera un terremoto de unas determinadas características y geometría. El modelo de Okada caracteriza dicho terremoto con una serie de parámetros. En el siguiente estudio se evaluará la sensibilidad de la inundación por tsunamis en la zona costera ante los cambios en los valores de dichos parámetros. Para ello, se ha tomado como referencia el trabajo previo de Padilla (2020) en el que se realizó un análisis de la peligrosidad de alta resolución para la localidad gaditana de Chipiona. Para dicho análisis, Padilla utilizó una fuente generadora del tsunami en el golfo de Cádiz, denominada, Cádiz Wedge Fault”, y utilizó el terremoto asociado a dicha fuente como base para la elaboración de mapas de inundación. En este estudio, se han realizado variaciones a los parámetros de la fuente utilizada por Padilla, para evaluar la sensibilidad del resultado a cada uno de ellos, por comparación con el resultado de Padilla, y estimar de esta manera la relevancia de la variación de cada uno de ellos. Así, se efectuaron diferentes simulaciones con el modelo COMCOT (Wang et al., 2011) de diversos escenarios reales e hipotéticos de propagación de tsunamis generados en dicha falla. Además, se realizó una simulación cambiando las condiciones de contorno presentes del caso inicial. Como resultado, se caracterizaron las zonas potencialmente inundables mediante mapas de inundación y gráficos de sensibilidad en los cuales se presentan datos normalizados de profundidad, velocidad, arrastre y arribo. Los resultados indican que los parámetros de Okada más sensibles son la magnitud del sismo, el coeficiente de Manning y la posibilidad de presentar barreras naturales a lo largo de la costa con unas variaciones del más del 37% al 29% en el área inundada ABSTRACT: Natural disasters are defined by the European Environment Agency (EEA) as those violent, sudden and destructive changes in the environment whose cause is not due to human activity, but natural phenomena. The study of Tsunamis has been widely addressed in recent decades because they occur as relatively infrequent natural events, but with the highest mortality rates. The possibility of a tidal wave affecting the Spanish coast is real and its occurrence is unpredictable. Therefore, adequate management is necessary in the areas of prevention and preparedness. The importance of tsunami hazard studies lies in the fact that they provide clarity regarding the degree of danger to which citizens are exposed. This situation highlights the need to carry out tsunami risk studies, generate early advertencia systems and define, take and promote strategies to mitigate the impact of tsunamis at a local or regional scale, in order to protect the population exposed to these possible events. It is common for tsunami hazard analysis to be carried out through numerical modeling of historical or potential events. In these simulations it is necessary to characterize the tsunami-generating earthquake, which is done through the definition of a series of parameters whose variability affects the result of the simulation and the impact on the flood zones. In general, Okada's model (1985) is accepted as an adequate method to represent the displacement of the free surface generated by an earthquake of certain characteristics and geometry. Okada's model characterizes said earthquake with a series of parameters. In the following study, the sensitivity of tsunami inundation in the coastal zone to changes in the values of these parameters will be evaluated. To do this, the previous work by Padilla (2020) has been taken as a reference, in which a high-resolution hazard analysis was carried out for the Cadiz town of Chipiona. For this analysis, Padilla used a tsunami-generating source in the Gulf of Cadiz, called the Cadiz Wedge Fault, and used the earthquake associated with said source as the basis for preparing flood maps. In this study, variations have been made to the parameters of the source used by Padilla, to evaluate the sensitivity of the result to each of them, by comparison with the result of Padilla, and thus estimate the relevance of the variation of each. one of them. Thus, different simulations were carried out with the COMCOT model (Wang et al., 2011) of various real and hypothetical scenarios of propagation of tsunamis generated in said fault. In addition, a simulation was carried out changing the present boundary conditions of the initial case. As a result, the potentially floodable areas were characterized by means of flood maps and sensitivity graphs in which normalized data of depth, speed, drag and arrival are presented. The results show that the most sensitive Okada parameters are the magnitude of the earthquake, the Manning coefficient and the possibility of presenting natural barriers along the coast with variations of more than 37% to 29% in the flooded area. Máster en Ingeniería costera y portuaria

Published

2022

48. The paleotsunami record of the Auckland region and implications for understanding tsunami hazards.

Author

Clark, Kate and Morgenstern, Regine

Subjects

*TSUNAMIS, *TSUNAMI warning systems, *BARRIER islands, *HISTORICAL source material, *FIELD research, *HAZARDS, *COASTS

Abstract

The Auckland region does not have a historic record of significant tsunamis but modelling suggests the eastern coastline could be exposed to tsunamis from the Kermadec Trench with wave amplitudes of up to 10 m on Great Barrier Island/Aotea and 1–5 m on the mainland. Paleotsunami research could contribute to filling the disconnect between historic records and tsunami modelling by providing a tsunami record over a time span of thousands of years that is more likely to capture the long recurrence intervals of great subduction earthquakes at the Kermadec Trench. Here we review existing paleotsunami information and results of new field studies in the Auckland region (primarily on Great Barrier Island/Aotea). Three sites (Tāwharanui, Whangapoua Beach and Harataonga Bay) have strong evidence of Holocene paleotsunami but the dating of the inferred paleotsunamis at all sites is relatively poor. The coastline of Auckland and its neighbouring regions offer our most promising sites to better understand the size and frequency of large to great Kermadec Trench earthquakes and this information could be of critical importance for understanding tsunami risk in New Zealand. [ABSTRACT FROM AUTHOR]

Published

2022

49. The Dependency of Probabilistic Tsunami Hazard Assessment on Magnitude Limits of Seismic Sources in the South China Sea and Adjoining Basins.

Author

Li, Hongwei, Yuan, Ye, Xu, Zhiguo, Wang, Zongchen, Wang, Juncheng, Wang, Peitao, Gao, Yi, Hou, Jingming, and Shan, Di

Subjects

*TSUNAMIS, *EMERGENCY management, *SEISMOLOGY, *MATHEMATICAL bounds, *CONFIDENCE intervals

Abstract

The South China Sea (SCS) and its adjacent small basins including Sulu Sea and Celebes Sea are commonly identified as tsunami-prone region by its historical records on seismicity and tsunamis. However, quantification of tsunami hazard in the SCS region remained an intractable issue due to highly complex tectonic setting and multiple seismic sources within and surrounding this area. Probabilistic Tsunami Hazard Assessment (PTHA) is performed in the present study to evaluate tsunami hazard in the SCS region based on a brief review on seismological and tsunami records. 5 regional and local potential tsunami sources are tentatively identified, and earthquake catalogs are generated using Monte Carlo simulation following the Tapered Gutenberg-Richter relationship for each zone. Considering a lack of consensus on magnitude upper bound on each seismic source, as well as its critical role in PTHA, the major concern of the present study is to define the upper and lower limits of tsunami hazard in the SCS region comprehensively by adopting different corner magnitudes that could be derived by multiple principles and approaches, including TGR regression of historical catalog, fault-length scaling, tectonic and seismic moment balance, and repetition of historical largest event. The results show that tsunami hazard in the SCS and adjoining basins is subject to large variations when adopting different corner magnitudes, with the upper bounds 2-6 times of the lower. The probabilistic tsunami hazard maps for specified return periods reveal much higher threat from Cotabato Trench and Sulawesi Trench in the Celebes Sea, whereas tsunami hazard received by the coasts of the SCS and Sulu Sea is relatively moderate, yet non-negligible. By combining empirical method with numerical study of historical tsunami events, the present PTHA results are tentatively validated. The correspondence lends confidence to our study. Considering the proximity of major sources to population-laden cities around the SCS region, the tsunami hazard and risk should be further highlighted in the future. [ABSTRACT FROM AUTHOR]

Published

2017

50. Comment on Omira, Baptista and Matias (2015), 'Probabilistic Tsunami Hazard in the Northeast Atlantic from Near- and Far-Field Tectonic Sources'.

Author

Fonseca, Joao

Subjects

*PROBABILITY theory, *TSUNAMIS, *SEISMIC waves, *TSUNAMI hazard zones, *STRUCTURAL geology

Abstract

Omira et al. (Pure and Applied Geophysics 172:901-920, 2015) assess the probabilistic tsunami hazard in the NE Atlantic. While recognizing the importance of this type of study for the prioritization of risk mitigation measures, I take consider the issue with the way the results are estimated and presented. I argue that the communication of the hazard is flawed, the analysis suffered from compounded conservatism, and no estimate of the associated uncertainties is provided. [ABSTRACT FROM AUTHOR]

Published

2017