Sunday, December 19, 2021

Earthquake depth impacts potential tsunami threat

Earthquake depth impacts potential tsunami threat
Graphic showing how a tsunami works. Credit: Ocean Institute, modified by NOAA/ NWS/ 
CGS

Earthquakes of similar magnitude can cause tsunamis of greatly varying sizes. This commonly observed, but not well-understood phenomenon has hindered reliable warnings of local tsunamis.

Research led by University of Hawai'i (UH) at Mānoa scientists provides new insight that connects the characteristics of earthquakes—, depth where two  slip past each other and the rigidity of the plates involved—with the potential size of a resulting tsunami.

Previous researchers identified a special class of events known as tsunami earthquakes, which produce disproportionately large tsunamis for their magnitude. Kwok Fai Cheung, professor of Ocean and Resources Engineering in the UH Mānoa School of Ocean and Earth Science and Technology (SOEST), Thorne Lay from the University of California—Santa Cruz and co-authors discovered a straightforward explanation for this conundrum. Their findings were published recently in Nature Geoscience.

Using computer models, the team incorporated  that produce earthquakes and tsunamis with a wide range of observations of real-world events, including those classified as tsunami earthquakes. The model results demonstrated that for a given earthquake magnitude, if the rupture extends to  in the less rigid part of the plate, the resulting tsunami is larger than if the rupture is deeper.

"In a subduction zone, the upper plate is thinner and less rigid than the underthrusting plate near the trench," explained Cheung. "A concentrated near-trench or shallow rupture produces relatively weak ground shaking as recorded by seismometers, but the displaced water in the overlying  has enhanced energy and produces shorter tsunami waves that amplify at a high rate as they move toward the shore."

Earthquake depth impacts potential tsunami threat
On September 29, 2009, a tsunami caused substantial damage and loss of life in American
 Samoa, Samoa, and Tonga. The tsunami was generated by a large earthquake in the 
Southern Pacific Ocean. Credit: NOAA

"Earthquake and tsunamigenic processes are complex, involving many factors that vary from one event to another," said Lay, professor of Earth and Planetary Sciences at UC Santa Cruz. "We utilized a simplified numerical model to isolate key earthquake parameters and evaluate their importance in defining tsunami size."

Having verified that the presence of shallow earthquake rupture can be a more significant factor than the earthquake magnitude for the resulting tsunami size led the researchers to an important question: Can earthquake magnitude continue to be used as the primary indication of potential tsunami impacts?

"The practice of using earthquake magnitude to estimate potential tsunami threat has led to poor predictive capability for tsunami impacts, and more information about the source is required to do better," said Cheung.

An important aspect of this interdisciplinary research is the synergy of expertise in seismology, with Lay, and tsunamis, with Cheung's research group, applied to a large set of observations. This study motivates development of new seismological and seafloor geodesy research that can rapidly detect occurrence of shallow rupture in order to achieve more reliable tsunami warning.

While shorelines throughout the Pacific Ocean and along the "Ring of Fire" are vulnerable to tsunamis, the situation is most critical for coastal communities near the earthquake, where the tsunami arrives quickly—when detailed information about the  is not yet available.

Cheung and Lay continue their collaboration to investigate prehistorical, historical, and future  events to better understand the hazards posed to coastal communities and enable more accurate warning systems.

Artificial intelligence could be used to accurately predict tsunamis
More information: Kwok Fai Cheung et al, Tsunami size variability with rupture depth, Nature Geoscience (2021). DOI: 10.1038/s41561-021-00869-z
Journal information: Nature Geoscience 
Provided by University of Hawaii at Manoa 

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