Tsunamis are one of the most destructive disasters in the ocean. Large tsunamis are mostly generated by earthquakes, and they can propagate across the ocean without significantly losing energy. During the shoaling process in coastal areas, the wave amplitude increases dramatically, causing severe life loss and property damage. There have been frequent tsunamis since the 21st century, drawing the attention of many countries on the study of tsunami mechanism and warning. Tsunami records also play an essential role in deriving earthquake rupture models in subduction zones.
A recent paper entitled "Tsunamis and tsunami warning: recent progress and future prospects" by Dr. Chao An from Shanghai Jiao Tong University reviews the recent research progress of earthquake-generated tsunamis, from the aspects of tsunami generation, propagation, inversion and warning. The paper was published on Science China Earth Sciences recently.
On tsunami generation, the paper analyzes three assumptions adopted in tsunami modeling and the associated errors, i.e., neglecting earthquake rupture process, assuming sea surface profile mimics seafloor deformation, and ignoring water compressibility. On tsunami propagation, popular simulation techniques are based on shallow water wave equations or Bousinessq equations of weak nonlinearity and weak dispersion; the paper reviews research results on the effects of Earth elasticity, water compressibility and ocean stratification. On tsunami inversion, the paper summarizes popular inversion methods including finite-fault inversion, initial sea surface profile inversion and time reversal method. The paper points out that tsunami data are of essential importance to constrain earthquake rupture parameters, but it has limited spatial and temporal resolution. On tsunami warning, the paper concludes that tsunami buoys are the most reliable way for tsunami warning. Without tsunami buoys, it is potentially possible to obtain accurate tsunami predictions by estimating the overall earthquake rupture characteristics and constructing uniform slip models (Table 1). Lastly, the paper briefly introduces the newly-developed method, i.e., Probabilistic Tsunami Hazard Assessment (PTHA), and points out that a possible improvement is to take regional geological structures into consideration.
By reviewing the most recent tsunami research, the following conclusions are obtained:
- Since the 2004 Sumatra tsunami, there have been more and more tsunami measurements. As a result, a lot of research has been done and the research methodologies have been well developed. With the deployment of ocean-bottom pressure sensors, it is possible to investigate multiple physical phenomena in an earthquake-tsunami event.
- By far tsunami buoys are still the most reliable ways of tsunami warning. If tsunami measurements are not available, one possible warning strategy is to estimate the overall characteristics of earthquakes use simplified uniform models to predict tsunami waves.
- Probabilistic methods are developed for tsunami hazard assessment in addition to traditional deterministic methods. A possible improvement is to take regional geological structures into consideration.
See the article:
An C. 2021. Tsunamis and tsunami warning: Recent progress and future prospects. Science China Earth Sciences, 64(1), 191-204,