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- Title
Shaken and Stirred: A Comparative Study of Earthquake‐Triggered Soft‐Sediment Deformation Structures in Lake Sediments.
- Authors
Molenaar, Ariana; Wils, Katleen; Van Daele, Maarten; Daxer, Christoph; Dubois, Nathalie; Grießer, Anja; Oswald, Patrick; Ramisch, Arne; Strasser, Michael; Moernaut, Jasper
- Abstract
Subaqueous paleoseismic studies used soft sediment deformation structures (SSDS) to discern the shaking strength of past earthquakes, as the deformation degree of SSDS related to Kelvin Helmholtz Instability evolves from disturbed lamination and folds to intraclast breccia with higher peak ground accelerations (PGA). We lack comparative studies of different sediment types with SSDS related to earthquakes from different seismogenic sources to comprehend how these factors modulate earthquake‐induced deformation. Here, we compile sediment records with seven earthquake‐triggered SSDS from 10 lakes with organic‐, carbonate‐, siliciclastic‐, and diatom‐rich sediment from three subduction zones and one collisional setting. We target basin sequences with slope angles <0.65° to reduce the influence of gravitational downslope stress. We find that even minimal increases in slope angle, maximal 1°, lead to higher deformation degrees and, for some earthquakes, SSDS are only present at >0.65°. Fine‐grained clastics enhance sediment susceptibility to deformation, whereas abundant diatoms reduce it, demonstrating the influence of composition. Deformation correlates best with PGA and the vicinity of the earthquakes, suggesting that high frequency shaking promotes deformation. In addition, deformation only occurs above a minimum magnitude dependent on sediment composition, and higher deformation degrees in our studied basin sedimentary sequences only above Mw 4.9 for all sediment types, suggesting that sufficient duration of shaking—magnitude correlates with duration—is essential for SSDS development. We advise taking multiple cores on gentle slopes to study SSDS—additional to basin cores—to resolve small magnitude local earthquakes and relative differences in frequency content of past events. Plain Language Summary: Earthquakes can deform sediment and store information on the shaking strength of past earthquakes within these structures. Therefore, studying deformation records can help society to understand the recurrence and magnitude of past earthquakes. To successfully apply this method, we need to understand exactly how seismic shaking interacts with the sediment on the lake floor. However, we lack studies investigating how sediment composition modulates deformation or which characteristics of an earthquake control deformation. To fill this knowledge gap, we compare the deformation records of 10 lakes with different sediment types caused by earthquakes with different shaking characteristics. Our data show that high concentrations of fine mineral grains within the sediment can ease earthquake‐triggered deformation, whereas abundant diatoms—a type of algae—makes sediment more resistant. Furthermore, we propose that mainly the high frequency component of seismic waves and sufficient duration of the earthquake are critical to deform sediment. We claim that deformations are a valuable addition to other sedimentological records of past earthquakes as they can resolve relative differences between the shaking characteristics of past earthquakes. Key Points: Sediment composition modulates sediment sensitivity to deformation as fine‐grained sediment increases and diatoms decrease sensitivityAside from strong seismic shaking, sufficient high frequency content and duration of seismic waves are a prerequisite for deformationFor paleoseismology, we advise taking multiple cores on gentle slopes to study deformations and in the flat basin to study event deposits
- Subjects
LAKE sediments; FOSSIL diatoms; PALEOSEISMOLOGY; SEDIMENTARY basins; SEISMIC waves; COMPOSITION of sediments; SUBDUCTION zones; EARTHQUAKE magnitude
- Publication
Geochemistry, Geophysics, Geosystems: G3, 2024, Vol 25, Issue 6, p1
- ISSN
1525-2027
- Publication type
Article
- DOI
10.1029/2023GC011402