Holocene deformation of a transform zone: paleoseismological and morphotectonics studies of the Húsavík-Flatey Fault in the Tjörnes Fracture Zone in North Iceland
Understanding the geometry, the earthquake history and the rate of defor- mation of a fault is crucial to assess the seismic behaviour of active faults. In particular, Oceanic Transform Faults (OTFs) lie at the bottom of the oceans, making it difficult to study their long-term behaviour. The Hu ́sav...
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| Other Authors: | , , , , , |
| Format: | Doctoral or Postdoctoral Thesis |
| Language: | English |
| Published: |
2023
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10754/696576 https://doi.org/10.25781/KAUST-HX243 |
| Summary: | Understanding the geometry, the earthquake history and the rate of defor- mation of a fault is crucial to assess the seismic behaviour of active faults. In particular, Oceanic Transform Faults (OTFs) lie at the bottom of the oceans, making it difficult to study their long-term behaviour. The Hu ́sav ́ık Flatey Fault (HFF) in North Iceland is a partially exposed OTF and therefore is a good labo- ratory to study the characteristics of an OTF. In this study, we conduct the first paleoseismological and morphotectonic study of the HFF and provide information on the earthquake history and slip rate of the fault. In the first part, we investigate the occurrence of past earthquakes on the HFF by building the first earthquake catalogue of the HFF for the Holocene period. To do so, we excavated paleoseismological trenches in two locations along the HFF to identify past earthquakes and constrain their timing. Our catalogue suggests a periodic behaviour of the seismicity along the HFF with a return time of a characteristic earthquake of ∼ 500 years. Eventually, our catalogue indicates that the characteristic earthquake on the HFF has a maximum magnitude of 7.2 to 7.3. Then, in order to calculate the slip rate of the fault, we performed detailed morphotectonic analysis at different locations along the HFF, to measure dis- placement related to fault activity. We measured fault offset of river beds, al- luvial fans, glacial moraines and landslides, ranging from 10 cm to 150 m, to constrain the Holocene slip rate of the HFF. Additionally, we measured the offset of the edge of a peninsula to infer the Pleistocene slip rate of the HFF and we estimated the vertical Pleistocene slip rate from the vertical step across a volcanic shield. Combining these displacement measurements with direct dating (radio- carbon and tephra) and ages inferred from literature, we constrain a slip rate of 6 to 6.5 mm/yr on the HFF, steady since at least the late Pleistocene. Our work contributes to the characterization of the seismic behaviour of the ... |
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