TY - JOUR A1 - Koulakov, Ivan A1 - Sobolev, Stephan Vladimir A1 - Weber, Bernd A1 - Oreshin, Sergey A1 - Wylegalla, Kurt A1 - Hofstetter, Rami T1 - Teleseismic tomography reveals no signature of the Dead Sea Transform in the upper mantle structure JF - Earth and planetary science letters N2 - We present results of a tomographic inversion of teleseismic data recorded at 48 stations of a temporary network which was installed in the area of the Dead Sea Transform (DST) and operated for 1 yr in the framework of the multidisciplinary DESERT Project. The 3366 teleseismic P and PKP phases from 135 events were hand picked and corrected for surface topography and crustal thickness. The inversion shows pronounced low-velocity anomalies in the crust, beneath the DST, which are consistent with recent results from local-source tomography. These anomalies are likely related to the young sediments and fractured rocks in the fault zone. The deeper the retrieved anomalies are quite weak. Most prominent is the high-velocity strip-like anomaly striking SE-NW. We attribute this anomaly to the inherited heterogeneity of lithospheric structure, with a possible contribution by the shallow Precambrian basement east of the DST and to lower crustal heterogeneity reported in this region by other seismic studies. We do not observe reliable signature of the DST in the upper mantle structure. Some weak indications of low-velocity anomalies in the upper mantle beneath the DST may well result from the down-smearing of the strong upper crustal anomalies. We also see very little topography of the lithosphere-asthenosphere boundary beneath the DST, which would generate significant horizontal velocity variations. These results are consistent with predictions from a recent thereto-mechanical model of the DST. Our tomographic model provides some indication of hot mantle flow from the deeper upper mantle rooted in the region of the Red Sea. However, resolution tests show that this anomaly may well be beyond resolution of the model. (c) 2006 Elsevier B.V. All rights reserved. KW - teleseismic tomography KW - Dead Sea Transform KW - lithosphere KW - asthenosphere KW - tectonophysics Y1 - 2006 U6 - https://doi.org/10.1016/j.epsl.2006.09.039 SN - 0012-821X VL - 252 IS - 1-2 SP - 189 EP - 200 PB - Elsevier CY - Amsterdam ER - TY - JOUR A1 - Petrunin, Alexey G. A1 - Rioseco, Ernesto Meneses A1 - Sobolev, Stephan Vladimir A1 - Weber, Michael H. T1 - Thermomechanical model reconciles contradictory geophysical observations at the Dead Sea Basin JF - Geochemistry, geophysics, geosystems N2 - The Dead Sea Transform (DST) comprises a boundary between the African and Arabian plates. During the last 15-20 m.y. more than 100 km of left lateral transform displacement has been accumulated on the DST and about 10 km thick Dead Sea Basin (DSB) was formed in the central part of the DST. Widespread igneous activity since some 20 Ma ago and especially in the last 5 m.y., thin (60-80 km) lithosphere constrained by seismic data and absence of seismicity below the Moho, seem to be quite natural for this tectonically active plate boundary. However, surface heat flow values of less than 50-60 mW/m(2) and deep seismicity in the lower crust (deeper than 20 km) reported for this region are apparently inconsistent with the tectonic settings specific for an active continental plate boundary and with the crustal structure of the DSB. To address these inconsistencies which comprise what we call the "DST heat-flow paradox," we have developed a numerical model that assumes an erosion of initially thick and cold lithosphere just before or during the active faulting at the DST. The optimal initial conditions for the model are defined using transient thermal analysis. From the results of our numerical experiments we conclude that the entire set of observations for the DSB can be explained within the classical pull-apart model assuming that the lithosphere has been thermally eroded at about 20 Ma and the uppermost mantle in the region have relatively weak rheology consistent with experimental data for wet olivine or pyroxenite. KW - heat flow KW - pull-apart basin KW - tectonophysics KW - thermomechanical modeling KW - transform fault Y1 - 2012 U6 - https://doi.org/10.1029/2011GC003929 SN - 1525-2027 VL - 13 IS - 8 PB - American Geophysical Union CY - Washington ER -