The Role of Near-Shore Bathymetry During Tsunami Inundation in a Reef Island Setting: A Case Study of Tutuila Island.- The “Tsunami Earthquake” of 13 April 1923 in Northern Kamchatka: Seismological and Hydrodynamic Investigations.- Tsunami Hazard Assessment of Coastal South Africa Based on Mega-Earthquakes of Remote Subduction Zones.- Far-Field Tsunami Hazard Assessment Along the Pacific Coast of Mexico by Historical Records and Numerical Simulation.- Tsunami Simulations in the Western Makran Using Hypothetical Heterogeneous Source Models from World’s Great Earthquakes.- Effect of Dynamical Phase on the Resonant Interaction Among Tsunami Edge Wave Modes.- On the Resonant Behavior of a Weakly Compressible Water Layer During Tsunamigenic Earthquakes.- Simulation of a Dispersive Tsunami due to the 2016 El Salvador–Nicaragua Outer-Rise Earthquake (Mw 6.9).- Ray Tracing for Dispersive Tsunamis and Source Amplitude Estimation Based on Green’s Law: Application to the 2015 Volcanic Tsunami Earthquake Near Torishima, South of Japan.- Tsunami Wave Run-up on a Vertical Wall in Tidal Environment.- Implications on 1 + 1 D Tsunami Runup Modeling due to Time Features of the Earthquake Source.- A Collaborative Effort Between Caribbean States for Tsunami Numerical Modeling: Case Study CaribeWave15.- Coastal Amplification Laws for the French Tsunami Warning Center: Numerical Modeling and Fast Estimate of Tsunami Wave Heights Along the French Riviera.- Evaluating the Effectiveness of DART® Buoy Networks Based on Forecast Accuracy.- Numerical Procedure to Forecast the Tsunami Parameters from a Database of Pre-Simulated Seismic Unit Sources.- Holocene Tsunamis in Avachinsky Bay, Kamchatka, Russia.- Historical Tsunami Records on Russian Island, the Sea of Japan.- Airburst-Generated Tsunamis.- Odessa Tsunami of 27 June 2014: Observations and Numerical Modelling.- Meteotsunami (“Marrobbio”) of 25–26 June 2014 on the Southwestern Coast of Sicily, Italy.
Tsunami science has evolved significantly since the occurrence of two of the most destructive natural disasters in recent times: the 26 December 2004 Sumatra tsunami that killed about 230,000 people along the coasts of 14 countries in the Indian Ocean and the 11 March 2011 Tohoku (Great East Japan) tsunami that killed almost 20,000 people and destroyed the Fukushima Daiichi nuclear power plant. As a result of these and many other destructive tsunamis that have occurred over just the last decade, scientists from around the world have come together to engage in tsunami research. The global community of researchers has also expanded by discipline, adapting advances in other sciences to study all aspects of tsunami hydrodynamics, detection, generation, and probability of occurrence. The papers presented in this third of three topical volumes of Pure and Applied Geophysics reflect the state of tsunami science during this time. Five papers from diverse geographic regions, ranging from off South Africa to northern Kamchatka, demonstrate the global nature of tsunami hazards. Six papers on tsunami hydrodynamic analysis and modeling form the core of this volume, similar to the previous two volumes of Global Tsunami Science. As a forefront of tsunami research, five papers discuss prehistoric tsunamis and tsunami generation by phenomena other than earthquakes. Finally, tsunami warning and real-time forecasting are important outcomes of tsunami science and are represented in this volume by four papers. Collectively, this volume highlights contemporary trends in global tsunami science, both fundamental and applied toward hazard assessment and mitigation. The volume is of interest to scientists and practitioners involved in all aspects of tsunamis from source processes to coastal impacts. Postgraduate students in geophysics, oceanography and coastal engineering – as well as students in the broader geosciences, civil and environmental engineering – will also find the book to be a valuable resource, as it combines recent case studies with advances in tsunami science and natural hazards mitigation.