Abstract
The instrumental seismicity that occurred in the Jordan Dead Sea transform region during the period 1900–2014 is compiled from all available sources. Some 492 phosphate mining explosions (M ≤ 3.9) are recognized and filtered from the data. Excluding these, it is found that 4448 earthquakes have occurred with magnitudes M ≥ 3.0. Only 572, 18 and 2 of these had magnitudes M ≥ 4, 5, and 6 in respective order. Average recurrence periods for the 5 and 6 magnitudes are 6.3 and 57 years. Much of these have occurred in sequences and swarms. The epicentral distribution of the compiled instrumental seismicity data shows very good correlation with the general tectonics of the study region. All tectonic elements are active in the present with a noticeable hazard. The regional strike-slip faults of the transform proper remain the major sources of this hazard. They account for not less than 99% of the seismic energy released from all instrumental data. The calculated a-parameter of the whole transform is 6.6. It varies for all its strike-slip faults mostly in the range 6.0–6.6. The b-value of the whole transform and some of its major segments is 1.0. Others show b-variations in the range of 1.1–1.3. Such a- and b-values imply recurrence periods of 38 years and 395 years for the 6 and 7 magnitude earthquakes. Such values, their variations and the seismic moment calculations clearly indicate an appreciable level of seismic hazard associated with all segments. This hazard appears to be highest for Al Ghab segment, followed by Beqa’a and Wadi Araba segments, respectively. The other three segments appear to be of lower hazard. The seismicity of this region is very shallow. More than 99% of the seismic energy has been released from the brittle granitic upper crust whose thickness is about 21 km and its Poisson’s ratio is 0.25. More than 93.6% of the energy was released from its upper 10 km. Very little energy is released from the underlying ductile basaltic crust whose Poisson’s ratio is 0.29. The calculated seismic slip rate along the Whole Jordan Dead Sea transform is 0.54 cm/year if the fault depth is assumed 10 km. It increases to 0.77 and 1.07 cm/year if the fault depth is reduced to 7 and 5 km, respectively. These slip rates are comparable with the long-term geologically deduced rate of 1 cm/year.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abdel-Fattah A, Hussein H, Ibrahim E, Abu El Atta A (1997) Fault plane solutions of the 1993 and 1995 Gulf of Aqaba earthquakes and their tectonic implications. Ann Geophys 40(6)
Abdel-Fattah A, Hussein H, El-Hady S (2006) Another look at the 1993 and 1995 Gulf of Aqaba earthquakes from the analysis of teleseismic waveforms. Acta Geophysica 54(3):260–279
Al-Qaryouti M (1990) Earthquake sequences and swarms: a characteristic of the seismicity of the Jordan rift, M.Sc. Thesis, Jordan University, Amman
Ambraseys NN (2009) Earthquakes in the Mediterranean and Middle East: a multidisciplinary study of seismicity up to 1900. Cambridge University Press, Cambridge
Ambraseys NN, Melville CP, Adams RD (1994) The seismicity of Egypt, Arabia and the Red Sea: a historical review. Cambridge Univ, Press, Camridge, U. K.
El-Isa ZH (1983) Seismic risk in Jordan, Proc. 1st Jordanian Geological Conference, Amman, pp. 1–18.
El-Isa ZH (1985) Earthquake studies of some archaeological sites in Jordan, in Hadid, A. (edt), Studies in the history and archaeology of Jordan, II, Dept. of Antiq., Amman, PP 229–235.
El-Isa ZH (1988) Seismic and seismological studies of the Jordan Dead Sea transform, science bull. Sanaa University 6:53–72
El-Isa ZH (1990) Lithospheric structure of the Jordan-Dead Sea transform from earthquake data. Tectonophysics 180:29–36
El-Isa Z (1992) Seismicity of the Wadi Araba-Dead Sea region. Geology Arab World:245–253
El-Isa ZH (2013) Continuous-cyclic variations in the b-value of the earthquake frequency-magnitude distribution. Earthq Sci. doi:10.1007/s11589-013-0037-9
El-Isa ZH, Al Shanti A (1989) Seismicity and tectonics of the Red Sea and western Arabia. Geophy J Int 97(3):449–457
El-Isa ZH, Eaton DW (2013) Spatiotemporal variations in the b-value of earthquake magnitude-frequency distributions: classification and causes. Tectonophysics. doi:10.1016/j.tecto.2013.12.001
El-Isa ZH, Mustafa H (1986) Earthquake deformations in the Lisan deposits and seismotectonic implications. Geophys J R Astron Soc 86:413–424
El-Isa ZH, Merghelani H, Bazzari M (1984) The Gulf of Aqaba earthquake swarm of 1983 January–April. Geophys J R Astron Soc 78(3):711–722
El-Isa ZH, Mechie J, Prodehl C, Makrris J, Rihm R (1987a) A crustal structure study of Jordan derived from seismic refraction data. Tectonophysics 138:235–253
El-Isa ZH, Mechie J, Prodehl C (1987b) Shear velocity structure of Jordan from explosion seismic data. Geophys J R astr SOC 90:265–281
Fiedler G (1974) Local b-values related to seismicity. Tectonophysics 23(3):277–282
Girdler RW (1990) The Dead-Sea transform-fault system. Tectonophysics 180:1–13
Harajli M, Sadek S, Asbahan R (2002) Evaluation of the seismic hazard of Lebanon. J Seismology 6:257–277
Hofstetter R, Klinger Y, Amrat AQ, Rivera L, Dorbath L (2007) Stress tensor and focal mechanisms along the Dead Sea fault and related structural elements based on seismological data. Tectonophysics 429(3–4):165–181
Khair K, Karakaisis GF, Papadimitriou EE (2000) Seismic zonation of the Dead Sea transform fault area. Ann Geofis 3:61–79
Klinger Y, Avouac J, Abou Karaki N, Dorbath L, Bourles D, Reyss J (2000) Slip rate on the Dead Sea transform fault in northern Araba valley (Jordan). Geophys J Int 142(3):755–768
Pinar A, Turkelli N (1997) Source inversion of the 1993 and 1995 Gulf of Aqaba earthquakes. Tectonophysics 283(1–4):279–288
Quennell AM (1958) The structural and geomorphic evolution of the Dead Sea rift, quart. J Geol Soc Lond 114:4–24
Quennell AM (1959) Tectonics of the Dead Sea Rift, Proc. 20th Intern. Geol. Congress, Mexico, 1956, ASGA, PP 385–403.
Quennell A (1984) The western Arabia rift system. Geol SocLond, Spec Publ 17(1):775
Robinson R (1979) Variation of energy release, rate of occurrence and b-value of earthquakes in the main seismic region, New Zealand. Phys Earth Planet Inter 18(3):209–220
Sahie O, Saikia M (1994) The b value before the 6th august, 1988 India-Myanmar border region earthquake–a case study. Tectonophysics 234(4):349–354
Salamon A, Hofstetter A, Garfunkel Z, Ron H (1996) Seismicity of the eastern Mediterranean region: perspective from the Sinai subplate. Tectonophysics 263:293–305
Shapira, A., Hofstetter, R., Abdallah, A.Q.F., Dabbeek, J. and Hays, W. 2007. Earthquake hazard assessments for building codes - final report. Rep. No. M18–057, submitted to the U.S. Agency for International Development, Bureau for Economic Growth, Agriculture and Trade.
Smith W (1981) The b-value as an earthquake precursor. Nature 289:136–139
Smith W (1986) Evidence for precursory changes in the frequency-magnitude B-value. Geophys J R Astron Soc 86(3):815–838
Wyss M, Brune JN (1968) Seismic moment, stress, and source dimensions for earthquakes in the California-Nevada region. J Geophys Res 73:4681–4694
Wyss M, Bodin P, Habermann R (1990) Seismic quiescence at Parkfield: an independent indication of an imminent earthquake. Nature 345:426–428
Acknowledgements
This work has been accomplished during a sabbatical the author spent at the University of Michigan, Ann Arbor with financial support from the University of Jordan, Amman. Professor Jeroen Ritsema is very much thanked for inviting me and supplying me with the required facilities to complete this work. Lengthy discussions with him have been very useful. The seismicity data sources including the ISC, JSO, and NEIC are very much thanked for the use of their data catalogues.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
El-Isa, Z.H. The instrumental seismicity of the Jordan Dead Sea transform. Arab J Geosci 10, 203 (2017). https://doi.org/10.1007/s12517-017-3000-6
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12517-017-3000-6