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Data Resources Category Scientific Paper
Research Title Seismic Wide-Angle Reflection / Refraction Profiling From The DESIRE Project Reveals The Deep Structure Across The Southern Dead Sea Basin

Published by (sources)

American Geophysical Union, Fall Meeting 2007, abstract #T43A-1077

Carried out by (authors)

Weber, M Mechie, J Ab-Ayyash, K Ben-Avraham, Z Radwan J. El-Kelani Qabbani, I DESIRE Group
Issue Year 2007
Abstract As part of the DESIRE project a 240 km long seismic wide-angle reflection / refraction (WRR) profile was completed in spring 2006 across the Dead Sea Transform (DST) in the region of the southern Dead Sea basin. The DST with a total of about 105 km multi-stage left-lateral shear since about 18 Ma ago, accommodates the movement between the Arabian and African plates. It connects the spreading centre in the Red Sea with the Taurus collision zone in Turkey over a length of about 1100 km. With a sedimentary infill of about 10 km in places, the southern Dead Sea basin is the largest pull-apart basin along the DST and one of the largest pull-apart basins on Earth. The WRR measurements comprised 11 shots recorded by 200 three-component and 400 one- component instruments spaced 300 m to 1.2 km apart along the whole length of the E-W trending profile. Models of the P-wave velocity structure derived from the WRR data show that the sedimentary infill associated with the formation of the southern Dead Sea basin is about 8.5 km thick beneath the profile. With around an additional 2 km of older sediments, the depth to the seismic basement beneath the southern Dead Sea basin is about 11 km below sea level beneath the profile. In contrast, the interfaces below about 20 km depth, including the top of the lower crust and the Moho, show less than 3 km variation in depth beneath the profile as it crosses the southern Dead Sea basin. Thus the Dead Sea pull-apart basin is essentially an upper crustal feature with N-S upper crustal extension associated with the left-lateral motion along the DST. The boundary between the upper and lower crust at about 20 km depth must act as a decoupling zone. Thermo-mechanical modelling of the Dead Sea basin supports such a scenario
 

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