VISCOELASTIC LITHOSPHERE DEFORMATION MODEL BASED ON FAULT STRENGTH PARAMETERS TO SIMULATE STRAIN ACCUMULATION AROUND THE NORTHERN GREAT SUMATRAN FAULT
The Great Sumatran Fault is a 1900-km strike-slip fault and divided into northern, central, and southern parts. Each part has its fault strength, deformation pattern, and seismic history. Based on its seismic activity, The Great Sumatran Fault has generated many large earthquakes along the fault....
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/67340 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The Great Sumatran Fault is a 1900-km strike-slip fault and divided into northern,
central, and southern parts. Each part has its fault strength, deformation pattern,
and seismic history. Based on its seismic activity, The Great Sumatran Fault has
generated many large earthquakes along the fault. These earthquakes occur when
the strain accumulated is suddenly released along the fault. Therefore, modeling
the accumulated strain on the lithospheric deformation is one way to understand
the seismicity pattern in the northern Sumatran Fault. The strain accumulation
model was carried out based on the fault strength in the northern Sumatra Fault,
especially the North Aceh, Central Aceh, South Aceh, North Tripa, South Tripa
and Renun segment, according to the average slip rate observed. The lithosphere
deformation of the northern Sumatra Fault is modeled using the finite-element
method by applying elastic materials in the upper crust and viscoelastic materials
in the lower crust and upper mantle. Based on the viscoelastic lithosphere
deformation model, locking and creeping events appear to affect the deformation
where the locking percentage is 75%, in accordance with the average slip rate of
15-16 mm/year in the Sumatra Fault. However, the subduction and forward arc
sliver movement need to be considered to model the lithosphere deformation.
Adding the effect of fore-arc sliver movement can shorten the strain accumulation
process by up to 2.7x shorter. From these models, we obtained the friction
coefficient for each segment, e.g., North Aceh is 0.06, Central and South Aceh is
0.07, North Tripa is 0.08, South Tripa is 0.13, and Renun is 0.21. The model with
different friction in each segment is in accordance with the seismicity pattern in the
northern Sumatra Fault. Still, the effect of stress transfer due to earthquake
subduction, especially in the North Tripa and South Tripa areas, needs to be
considered. Furthermore, a small difference in friction strength (0.01) in the Aceh
Utara-Aceh Tengah and Aceh Selatan-Tripa Utara segment can also explain the
earthquake that occurred at the boundary between these segments. |
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