News Release

Self-similar fractal stress is more suitable for destructive scenario earthquake simulation

Peer-Reviewed Publication

Science China Press

Horizontal PGV and intensity distribution

image: 

Horizontal PGV and intensity distribution under the four models, (a) the horizontal uniform stress model, and the self-similar stress model with (b) ac =50 km, (c) ac = 40 km, (d) ac =30 km, where ac is the characteristic length that determines the stress roughness.

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Credit: ©Science China Press

Scenario earthquakes are practically useful in assessing earthquake hazards along active faults. However, determining the sources of destructive scenario earthquakes, particularly when dealing with heterogeneous stresses, can be challenging. Researchers from University of Science and Technology of China conducted a study on the Tanlu Fault, the largest strike-slip fault in eastern China, demonstrating that self-similar fractal stress is more suitable for characterizing the sources of scenario earthquakes.

The study concentrated on the Xinyi-Sihong segment of the Tanlu fault, an area known to potentially sustain a M7.5 earthquake. The hypocenter was placed near 10 km depth around Suqian, where a noticeable contrast between high and low velocities indicates a potential nucleation point. The team effectively constrained the fault rupture length and width according to the scaling laws that govern large earthquakes.

To have a better understanding of the physical process of the rupture propagation coupling with stress heterogeneity, researchers simulated the scenario earthquake rupture process using the finite difference method. A depth-dependent background normal stress is incorporated. They utilized the self-similar fractal stress perturbation to characterize the stress heterogeneity in the fault-strike direction. Compared with the horizontal uniform stress model, researchers shown that the source time function of the horizontal uniform stress model closely resembles that of the Haskell model. However, the self-similar stress model aligns more closely with those observed in real earthquakes.

The dynamic rupture simulations provided insights into how various stress conditions influence the rupture behavior and ground motion. Notably, the self-similar stress model, which incorporates a shorter characteristic length, suggests a rougher initial stress and a more heterogeneous slip distribution. To the north of the epicenter near Suqian, the models predict more intense vibrations due to the nearby low-velocity zone and high slip rates on the fault. This area is situated within the 9-degree intensity zone, highlighting the importance of targeted earthquake preparedness and building resistance capabilities.

The study underscores the importance of coupling self-similar fractal stresses in scenario earthquake simulations. By advancing our understanding of the stress heterogeneity effect in earthquake rupture propagation and ground motions, scientists can provide better guidelines for infrastructure development and disaster preparedness strategies.    

See the article:

Hu F, Yao H, Yu H, Lu Z, Hou J, Luo S, Shao Z, Chen X. 2024. Influence of self-similar stresses on scenario earthquake construction: An example along the Tanlu Fault. Science China Earth Sciences, 67(5): 1687–1697, https://doi.org/10.1007/s11430-023-1239-8


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