Limited Shallow Slip for the 2020 Simeonof Earthquake, Alaska, Constrained by GNSS‐Acoustic

On 18 November 2022, a large earthquake struck offshore southern Sumatra, generating a tsunami with 25 cm peak amplitude recorded at tide gauge station SBLT. Our W‐phase solution indicates a shallow dip of 6.2°, compatible with long‐period surface wave radiation patterns. Inversion of teleseismic body waves indicates a shallow slip distribution extending from about 10 km deep to near the trench with maximum slip of ∼4.1 m and seismic moment of Nm (MW 7.3). Joint modeling of seismic and tsunami data indicates a shallow rigidity of ∼23 GPa. We find a low moment‐scaled radiated energy of , similar to that of the 2010 MW 7.8 Mentawai event () and other tsunami earthquakes. These characteristics indicate that the 2022 event should be designated as a smaller moment magnitude tsunami earthquake compared to the other 12 well‐documented global occurrences since 1896. The 2022 event ruptured up‐dip of the 2007 MW 8.4 Bengkulu earthquake, demonstrating shallow seismogenic capability of a megathrust that had experienced both a deeper seismic event and adjacent shallow aseismic afterslip. We consider seismogenic behavior of shallow megathrusts and concern for future tsunami earthquakes in subduction zones globally, noting a correlation between tsunami earthquake occurrence and subducting seafloor covered with siliceous pelagic sediments. We suggest that the combination of pelagic clay and siliceous sediments and rough seafloor topography near the trench play important roles in controlling the genesis of tsunami earthquakes along Sumatra and other regions, rather than the subduction tectonic framework of accretionary or erosive margin.

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Representation and interpretation about underwater sound speed gradient field in the GNSS-A observation

Yokota,

Ishikawa,

Watanabe

et al. 2024

Geophysical Journal International

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Summary The Global Navigation Satellite System—Acoustic ranging combination technique (GNSS-A) is a seafloor geodetic observation technique that achieves an accuracy of centimeters by combining high-rate GNSS data with acoustic ranging. The technique determines the seafloor position by acoustic ranging between the sea surface and multiple seafloor stations, using GNSS data from the sea surface station. Here, the gradient state of the underwater sound speed structure (SSS) is a significant source of error. The open-source software GARPOS can reduce the effect from underwater gradient structures by retrieving the underwater disturbance as a parameter projected onto the sea surface and seafloor. To evaluate the effects of underwater disturbances, a quantitative comparison of the model parameters is necessary. In this study, we developed a representation method to evaluate features of the ocean field. Here, the expression method was described in the order of a formulation and an interpretation in the case of a two-dimensional cross section and extension to the case of an actual three-dimensional field. This method makes it possible to evaluate SSS states in the GNSS-A observations. As an example, we showed the correlation between the anomaly of the expressed ocean state and the anomaly of the seafloor station position, showing that this expression method is an effective index for correcting bias errors. Additionally, we used the data from sites located in the Kuroshio area, a strong current near Japan, to show that the ocean state can be quantitatively interpreted using this expression method.

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Limited Shallow Slip for the 2020 Simeonof Earthquake, Alaska, Constrained by GNSS‐Acoustic

Cited by 7 publications

References 35 publications

Geodetic Observations of Tectonic Deformation in Alaska and Western Canada: The EarthScope Revolution

Geodetic Observations of Tectonic Deformation in Alaska and Western Canada: The EarthScope Revolution

The 2022 M_W 7.3 Southern Sumatra Tsunami Earthquake: Rupture Up‐Dip of the 2007 M_W 8.4 Bengkulu Event

Representation and interpretation about underwater sound speed gradient field in the GNSS-A observation

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Limited Shallow Slip for the 2020 Simeonof Earthquake, Alaska, Constrained by GNSS‐Acoustic

Cited by 7 publications

References 35 publications

Geodetic Observations of Tectonic Deformation in Alaska and Western Canada: The EarthScope Revolution

Geodetic Observations of Tectonic Deformation in Alaska and Western Canada: The EarthScope Revolution

The 2022 MW 7.3 Southern Sumatra Tsunami Earthquake: Rupture Up‐Dip of the 2007 MW 8.4 Bengkulu Event

Representation and interpretation about underwater sound speed gradient field in the GNSS-A observation

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Product

Resources

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The 2022 M_W 7.3 Southern Sumatra Tsunami Earthquake: Rupture Up‐Dip of the 2007 M_W 8.4 Bengkulu Event