Observations of meteorological tsunamis along the south-west Australian coast

Pattiaratchi, Charitha; Wijeratne, Sarath

doi:10.1007/s11069-014-1263-8

Cited by 45 publications

(26 citation statements)

References 37 publications

(57 reference statements)

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“…Still, a number of high-frequency processes that substantially contribute to sea level extremes (such as tsunamis, meteotsunamis, and infragravity waves) cannot be properly assessed using hourly data. The science of tsunamis, due to their global importance and impact, has constantly been at the forefront of sea level research9, while the remainder of the high-frequency sea level signal, which can be defined as consisting of nonseismic sea level oscillations at tsunami timescales (NSLOTT), has been researched only locally10111213. The concept of NSLOTT events refers to all sea level oscillations except tsunamis that appear at periods between a few minutes to a few hours.…”

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confidence: 99%

Global mapping of nonseismic sea level oscillations at tsunami timescales

Vilibić

Šepić

2017

Sci Rep

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Present investigations of sea level extremes are based on hourly data measured at coastal tide gauges. The use of hourly data restricts existing global and regional analyses to periods larger than 2 h. However, a number of processes occur at minute timescales, of which the most ruinous are tsunamis. Meteotsunamis, hazardous nonseismic waves that occur at tsunami timescales over limited regions, may also locally dominate sea level extremes. Here, we show that nonseismic sea level oscillations at tsunami timescales (<2 h) may substantially contribute to global sea level extremes, up to 50% in low-tidal basins. The intensity of these oscillations is zonally correlated with mid-tropospheric winds at the 99% significance level, with the variance doubling from the tropics and subtropics to the mid-latitudes. Specific atmospheric patterns are found during strong events at selected locations in the World Ocean, indicating a globally predominant generation mechanism. Our analysis suggests that these oscillations should be considered in sea level hazard assessment studies. Establishing a strong correlation between nonseismic sea level oscillations at tsunami timescales and atmospheric synoptic patterns would allow for forecasting of nonseismic sea level oscillations for operational use, as well as hindcasting and projection of their effects under past, present and future climates.

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confidence: 99%

Global mapping of nonseismic sea level oscillations at tsunami timescales

Vilibić

Šepić

2017

Sci Rep

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“…Predicted meteotsunami heights of ∼70 cm (at Rovinj tide gauge) are practically of the same order of magnitude as tides and storm surges, and may considerably endanger the coastal infrastructure if occurring during high tide (and/or storm surge). Matching of a strong meteotsunami event and a high tide was for example found during a century record‐breaking sea level observations in Freemantle, Western Australia [ Pattiaratchi and Wijeratne , ]. High‐frequency oscillations should therefore be included into any assessment of risk of extreme sea levels in the region.…”

Section: Discussionmentioning

confidence: 99%

“…Meteorological tsunamis or meteotsunamis are rare, but destructive, tsunami‐like events which unexpectedly hit coastal areas, occasionally causing a widespread damage and even loss of human lives [ Ewing et al ., ; Vučetić et al ., ]. They are strongest in those bays and harbors which have large amplification factors [ Gomis et al ., ; Rabinovich , ], but they can also be high and destructive along the shorelines of wide shelves [ Sallenger et al ., ; Paxton and Sobien , ; Pattiaratchi and Wijeratne , ]. Meteotsunamis are most often generated by rapid air pressure changes (∼2 hPa/5 min) [ Vilibić et al ., ; Thomson et al ., ; Okal et al ., ; Šepić and Vilibić , ] and somewhat less often by intense wind disturbances (>20 m/s) [ de Jong and Battjes , ; Bechle and Wu , ; Šepić and Rabinovich , ].…”

Section: Introductionmentioning

confidence: 99%

Northern Adriatic meteorological tsunamis: Assessment of their potential through ocean modeling experiments

2015

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Potential for generation of meteotsunami waves via open ocean resonance has been documented for the shallow northern Adriatic, based on a set of barotropic numerical modeling experiments. Model simulations were forced by a bell‐shaped traveling atmospheric (air pressure, wind) disturbance, with shape and propagation parameters chosen in accordance with measurements done during several observed northern Adriatic meteotsunamis. Air pressure disturbances were found to generate much larger meteotsunami waves than wind disturbances, with wind disturbances having a limited influence in the very coastal and shallow areas only. Numerical simulations reveal that the most important factor for generation of large meteotsunami waves is matching between the speed of the atmospheric disturbance and the speed of long‐ocean waves. Already a small (∼10%) deviation from resonant conditions stops the wave growth and dramatically decreases height of predicted waves. A train of atmospheric disturbances can significantly increase maximum wave heights at selected locations at which multiple reflections and superimpositions of meteotsunami waves occur. Sensitivity of model simulations to resonant conditions and limited cross‐propagation width of atmospheric disturbance explain the localization of destructive meteotsunami waves in a limited area during destructive historic events. Mapping of maximum predicted wave heights indicates places with large meteotsunami hazard potential, matching the locations where real events were observed, and may be a useful tool for assessing vulnerability and risks in coastal areas during extreme sea level events.

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“…Even moderate meteotsunamis can have damaging impacts on boats and ships in harbors and small embayments (Thomson et al, ). Meteotsunami hazard is increased by additional sources of energy: (1) the wind stress (Bechle & Wu, ; De Jong & Battjes, ; Dragani et al, ; Pellikka et al, ; Whitmore & Knight, ), (2) the local high tide level (Horvath & Vilibic, ), and (3) a higher water level from a storm surge or high mean seasonal sea level (Pattiaratchi & Wijeratne, ).…”

Section: Tsunami Generation and Propagation: Causes Mechanisms And mentioning

confidence: 99%

Probabilistic Tsunami Hazard Analysis: Multiple Sources and Global Applications

Grezio

Babeyko²,

Baptista

et al. 2017

Reviews of Geophysics

198

165

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Applying probabilistic methods to infrequent but devastating natural events is intrinsically challenging. For tsunami analyses, a suite of geophysical assessments should be in principle evaluated because of the different causes generating tsunamis (earthquakes, landslides, volcanic activity, meteorological events, and asteroid impacts) with varying mean recurrence rates. Probabilistic Tsunami Hazard Analyses (PTHAs) are conducted in different areas of the world at global, regional, and local scales with the aim of understanding tsunami hazard to inform tsunami risk reduction activities. PTHAs enhance knowledge of the potential tsunamigenic threat by estimating the probability of exceeding specific levels of tsunami intensity metrics (e.g., run‐up or maximum inundation heights) within a certain period of time (exposure time) at given locations (target sites); these estimates can be summarized in hazard maps or hazard curves. This discussion presents a broad overview of PTHA, including (i) sources and mechanisms of tsunami generation, emphasizing the variety and complexity of the tsunami sources and their generation mechanisms, (ii) developments in modeling the propagation and impact of tsunami waves, and (iii) statistical procedures for tsunami hazard estimates that include the associated epistemic and aleatoric uncertainties. Key elements in understanding the potential tsunami hazard are discussed, in light of the rapid development of PTHA methods during the last decade and the globally distributed applications, including the importance of considering multiple sources, their relative intensities, probabilities of occurrence, and uncertainties in an integrated and consistent probabilistic framework.

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Observations of meteorological tsunamis along the south-west Australian coast

Cited by 45 publications

References 37 publications

Global mapping of nonseismic sea level oscillations at tsunami timescales

Global mapping of nonseismic sea level oscillations at tsunami timescales

Northern Adriatic meteorological tsunamis: Assessment of their potential through ocean modeling experiments

Probabilistic Tsunami Hazard Analysis: Multiple Sources and Global Applications

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