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Global Positioning System measurements of strain accumulation and slip transfer through the restraining bend along the Dead Sea fault system in Lebanon

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dc.contributor.author Gomez, Francisco
dc.contributor.author Karam, Gebran
dc.contributor.author Khawlie, Mohamad
dc.contributor.author McClusky, Simon
dc.contributor.author Vernant, Philippe
dc.contributor.author Reilinger, Robert
dc.contributor.author Jaafar, Rani
dc.contributor.author Tabet, Charles
dc.contributor.author Khair, Kamal
dc.date.accessioned 2016-02-11T07:10:38Z
dc.date.available 2016-02-11T07:10:38Z
dc.date.copyright 2007
dc.date.issued 2016-02-11
dc.identifier.issn 0956-540X en_US
dc.identifier.uri http://hdl.handle.net/10725/3039
dc.description.abstract Approximately 4 yr of campaign and continuous Global Positioning System (GPS) measurements across the Dead Sea fault system (DSFS) in Lebanon provide direct measurements of interseismic strain accumulation along a 200‐km‐long restraining bend in this continental transform fault. Late Cenozoic transpression within this restraining bend has maintained more than 3000 m of topography in the Mount Lebanon and Anti‐Lebanon ranges. The GPS velocity field indicates 4–5 mm yr−1 of relative plate motion is transferred through the restraining bend to the northern continuation of the DSFS in northwestern Syria. Near‐field GPS velocities are generally parallel to the major, left‐lateral strike‐slip faults, suggesting that much of the expected convergence across the restraining bend is likely accommodated by different structures beyond the aperture of the GPS network (e.g. offshore Lebanon and, possibly, the Palmyride fold belt in SW Syria). Hence, these geodetic results suggest a partitioning of crustal deformation involving strike‐slip displacements in the interior of the restraining bend, and crustal shortening in the outer part of the restraining bend. Within the uncertainties, the GPS‐based rates of fault slip compare well with Holocene‐averaged estimates of slip along the two principal strike‐slip faults: the Yammouneh and Serghaya faults. Of these two faults, more slip occurs on the Yammouneh fault, which constitutes the primary plate boundary structure between the Arabia and Sinai plates. Hence, the Yammouneh fault is the structural linkage that transfers slip to the northern part of the transform in northwestern Syria. From the perspective of the regional earthquake hazard, the Yammouneh fault is presently locked and accumulating interseismic strain. en_US
dc.language.iso en en_US
dc.title Global Positioning System measurements of strain accumulation and slip transfer through the restraining bend along the Dead Sea fault system in Lebanon en_US
dc.type Article en_US
dc.description.version Published en_US
dc.author.school SOE en_US
dc.author.idnumber 199590200 en_US
dc.author.woa N/A en_US
dc.author.department Civil Engineering en_US
dc.description.embargo N/A en_US
dc.relation.journal Geophysical Journal International en_US
dc.journal.volume 168 en_US
dc.journal.issue 3 en_US
dc.article.pages 1021-1028 en_US
dc.keywords Crustal deformation en_US
dc.keywords Dead Sea fault system en_US
dc.keywords Fault motion en_US
dc.keywords Global Positioning System (GPS) en_US
dc.keywords Neotectonics en_US
dc.keywords Transform faults en_US
dc.identifier.doi http://dx.doi.org/ 10.1111/j.1365-246X.2006.03328.x en_US
dc.identifier.ctation Gomez, F., Karam, G., Khawlie, M., McClusky, S., Vernant, P., Reilinger, R., ... & Barazangi, M. (2007). Global Positioning System measurements of strain accumulation and slip transfer through the restraining bend along the Dead Sea fault system in Lebanon. Geophysical Journal International, 168(3), 1021-1028. en_US
dc.author.email gkaram@lau.edu.lb
dc.identifier.url http://gji.oxfordjournals.org/content/168/3/1021.short


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