Earthquake And Tsunami Hazards Along Coasts Might Be Higher Than Expected
Two of the most destructive forces of nature—earthquakes and tsunamis—might actually be more of a threat than current estimates according to new research conducted by scientists at The University of New Mexico and the Nanyang Technological University published today in the journal Nature Geoscience.
The researchers developed a new method to assess earthquake and tsunami hazards represented by the most distant part of offshore subduction zones and found that the hazard might have been systematically underestimated in some areas, meaning that tsunami risk assessments should be redone given the new results. The findings have important implications for the mitigation of risk in affected areas worldwide, including Southeast Asia and the Pacific Rim, in the event of future earthquakes and tsunamis.
Megathrust earthquakes are among the most powerful earthquakes experienced worldwide and occur in subduction zones.
While the great majority of all earthquakes occur at plate boundaries, these tsunami-causing earthquakes mostly occur at convergent plate boundaries. These boundaries, also called subduction zones, are where oceanic crust is pushed and pulled beneath the continents triggering megathrust earthquakes, and are the regions where geologists expect future devastating tsunamis to come from. When these earthquakes affect the shallowest part of the fault near the seafloor, they have the potential to shift the seafloor upward and create devastating tsunamis as well.
The following animated map shows every recorded earthquake and tsunami in sequence as they occurred from January 1, 1901, through December 31, 2020, at a rate of 1 year per second. Megathrust earthquakes have the highest magnitude and generate the largest tsunami’s wave heights on the open ocean.
Understanding the potential rupture behavior of megathrusts, particularly in the shallow offshore part of the fault where most destructive tsunamis are generated, is therefore a critical task for geoscientists forecasting seismic and tsunami inundation hazards. The likelihood of seismic behavior is often assumed to be somewhat low in the shallow part of the fault, based on laboratory studies of recovered fault zone material.
The fault’s rate of slip deficit buildup can also be measured through the use of geodetic observations that track how the earth’s surface moves over time, for example by using highly precise GPS sensors installed on land, together with a model that relates how slip on the fault affects the movement of these stations. However, it is hard for scientists to use this technique to “see” what is going on in the shallowest part of the fault, because it is far from land, below miles of water, where traditional GPS instruments cannot operate.
Now, scientists at The University of New Mexico and the Nanyang Technological University (NTU) in Singapore have developed a new geodetic method for inferring this value that accounts for the interaction between different parts of the fault, resulting in a much more physically accurate result. Lindsey’s team noted that previous models have failed to take into account the fact that if the deep part of the fault is stuck between earthquakes, the shallow part can’t move either—it is in what they term a ‘stress shadow’ and there is no buildup of energy available to cause it to slip. By taking this effect into account, the team developed a technique that uses the same land-based data but results in a vast improvement in their ability to “see” the fault slip in the areas that are farthest from shore, allowing researchers to reassess the hazard presented by the offshore parts of subduction zones most prone to tsunami generation.
“We applied this technique to the Cascadia and Japan subduction zones and found that wherever deeper locked patches are present, the shallow fault must also have a high slip deficit—regardless of its own frictional properties,” said Eric Lindsey, an assistant professor in the UNM Department of Earth and Planetary Sciences who conducted the research while at the Earth Observatory of Singapore at NTU. “If these areas can slip seismically, global tsunami hazard could be higher than currently recognized. Our method identifies critical locations where seafloor observations could yield information about frictional properties of these faults in order to better understand their slip behavior.”
This study is important because it calls for a reassessment of previous models of tsunami hazard on megathrusts worldwide. Because this can be done with existing data, the reassessment can be done comparatively quickly as well. Hopefully, this will lead to better preparedness among coastal communities for future events.