Holocene faulting and earthquake recurrence along the Serghaya branch of the Dead Sea fault system in Syria and Lebanon

Gomez, Francisco; Meghraoui, Mustapha; Darkal, A.; Hijazi, F.; Mouty, Mikhail; Suleiman, Youssef; Sbeinati, R.; Darawcheh, Ryad; Al-Ghazzi, R.; Barazangi, Muawia

doi:10.1046/j.1365-246x.2003.01933.x

Cited by 104 publications

(100 citation statements)

References 51 publications

(77 reference statements)

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“…Recent plate tectonic models have begun to suggest that the northern portion of this transform may be characterized as transpressional in nature. Recent studies have identified clear evidence of active tectonism along the DSFS, including paleoseismic indicators, for the main fault branches along the northern 500 km of the DSFS (i.e., north of approximately 32.5° N) [1][2][3][4][5]. Results of these studies firmly refute recent assertions that the northern DSFS and the strike-slip faults in the Bekaa Valley are presently inactive [6,7].…”

Section: Introductionmentioning

confidence: 92%

Late Cenozoic uplift along the northern Dead Sea transform in Lebanon and Syria

Gomez

Khawlie

Tabet

et al. 2006

Earth and Planetary Science Letters

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Section: Introductionmentioning

confidence: 92%

Late Cenozoic uplift along the northern Dead Sea transform in Lebanon and Syria

Gomez

Khawlie

Tabet

et al. 2006

Earth and Planetary Science Letters

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“…It is one of the largest continental strike-slip faults in the world with more than 1000 km length and links the Red Sea seafloor-spreading center to the collision zone in SE Turkey. According to Butler et al (1997) and Gomez et al (2003) the DST can be subdivided into a southern and northern part, joined by a ~200 km long restraining bend (Lebanese segment). The DST has been active since the middle Miocene with a total displacement of 105 km in the south (Bartov et al, 1980;Eyal et al 1981;Garfunkel et al, 1981) and 70-80 km in the north (e.g.…”

Section: Regional Tectonic Settingmentioning

confidence: 99%

“…However, the analysis of the structural displacement has been proved controversial (Westaway, 2004;Mart et al, 2005). The estimated slip rate varies between 1 and 10 mm/a following different measurement techniques (field studies, GPS, e.g., Garfunkel et al, 1981;Klinger et al, 2000;Gomez et al, 2003;Pe'eri et al, 2002;Meghraoui et al, 2003).…”

Section: Regional Tectonic Settingmentioning

confidence: 99%

“…Previous structural studies which took place along several fault branches of the DST, such as the Arava fault (AF; e.g., Klinger et al, 2000;Diabat et al, 2004); the Serghaya fault (SF; e.g., Gomez et al, 2001;Gomez et al, 2003) and the Ghab (or Masyaf) fault (GF; e.g., Meghraoui et al, 2003;Chorowitz et al, 2005) suggest notable variations in the amount of displacement and the level of seismicity. Therefore, the question arises to what extent fault-related observations based on geophysical and geological investigations of individual fault segments are valid for large-scale strike-slip faults systems as a whole.…”

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confidence: 99%

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Different styles of faulting deformation along the Dead Sea Transform and possible consequences for the recurrence of major earthquakes

Janssen¹,

Hoffmann‐Rothe²,

Bohnhoff³

et al. 2007

Journal of Geodynamics

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We compare fault-related deformation of three segments of the major transform plate boundary between Africa and the Arabian plate, the Dead Sea Transform (DST), namely: the Arava/Araba fault (Jordan/Israel), the Serghaya fault and the Ghab fault (both Syria). These segments show both similarities and marked differences in faulting deformation and fluid-rock interactions. In the case of the Arava fault, fault damage occurs across a zone up to 300 m wide. A fault core/gouge zone is not exhibited.Along the Serghaya fault, the typical fault zone architecture with a main gouge zone and a damage zone of up to 100 m thickness is exposed. Effects of faulting in the Ghab segment are shown by subsidiary faults and the formation of fault breccias. As in the Arava fault segment, a fault core is not exposed. were active along Serghaya fault and Ghab fault, where fault rock cementation led to * Corresponding author. Fax: +49-331-288-1328, E-mail address: jans@gfz-potsdam.de 2 porosity reduction and lower permeability. Such low permeability could create domains of higher pore fluid pressure, which reduce the effective shear stress required for slip on the fault. These differences in fluid-rock interactions may have played an important role with respect to the occurrence of earthquakes. We suggest that the recurrence interval on a fault segment that recovers after an earthquake without fluid assisted healing (e.g. Arava fault) should be longer than on segments with strong fluidassisted healing (cementation; e.g. Serghaya fault, Ghab fault), given that the regional stress field is the same.

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“…The most recent large earthquake is the double shock of March 16, 1956 (Ms = 4.8-5.1) which killed 136 people, destroyed 6000 houses and damaged 17,000 houses (Brazee and Cloud 1984;Khair et al 2000). Seismological trenches have shown that the return period of devastating earthquakes is about 1100 years along the Yammouneh Fault ), 1500-1750 years along the Mount Lebanon Thrust ) and ~1300 years along Serghaya Faults (Gomez et al 2003).…”

Section: Application To Beirutmentioning

confidence: 99%

Using ambient vibration measurements for risk assessment at an urban scale: from numerical proof of concept to Beirut case study (Lebanon)

Salameh

Bard

Guillier

et al. 2017

Earth Planets Space

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Post-seismic investigations repeatedly indicate that structures having frequencies close to foundation soil frequencies exhibit significantly heavier damages (Caracas 1967; Mexico 1985; Pujili, Ecuador 1996; L' Aquila 2009). However, observations of modal frequencies of soils and buildings in a region or within a current seismic risk analysis are not fully considered together, even when past earthquakes have demonstrated that coinciding soil and building frequencies leads to greater damage. The present paper thus focuses on a comprehensive numerical analysis to investigate the effect of coincidence between site and building frequencies. A total of 887 realistic soil profiles are coupled with a set of 141 single-degree-of-freedom elastoplastic oscillators, and their combined (nonlinear) response is computed for both linear and nonlinear soil behaviors, for a large number (60) of synthetic input signals with various PGA levels and frequency contents. The associated damage is quantified on the basis of the maximum displacement as compared to both yield and ultimate post-elastic displacements, according to the RISK-UE project recommendations (Lagomarsino and Giovinazzi in Bull Earthq Eng 4(4): 2006), and compared with the damage obtained in the case of a similar building located on rock. The correlation between this soil/rock damage increment and a number of simplified mechanical and loading parameters is then analyzed using a neural network approach. The results emphasize the key role played by the building/soil frequency ratio even when both soil and building behave nonlinearly; other important parameters are the PGA level, the soil/rock velocity contrast and the building ductility. A numerical investigation based on simulation of ambient noise for the whole set of 887 profiles also indicates that the amplitude of H/V ratio may be considered as a satisfactory proxy for site amplification when applied to measurements at urban scale. A very easy implementation of this method, using ambient vibration measurements both at ground level and within buildings, is illustrated with an example application for the city of Beirut (Lebanon).

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Holocene faulting and earthquake recurrence along the Serghaya branch of the Dead Sea fault system in Syria and Lebanon

Cited by 104 publications

References 51 publications

Late Cenozoic uplift along the northern Dead Sea transform in Lebanon and Syria

Late Cenozoic uplift along the northern Dead Sea transform in Lebanon and Syria

Different styles of faulting deformation along the Dead Sea Transform and possible consequences for the recurrence of major earthquakes

Using ambient vibration measurements for risk assessment at an urban scale: from numerical proof of concept to Beirut case study (Lebanon)

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