Environmental Geology

, Volume 58, Issue 2, pp 371–380 | Cite as

Human-induced geological hazards along the Dead Sea coast

Special Issue
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Abstract

The Dead Sea is a terminal lake whose level is currently dropping at a rate of about 1 m per year due to the over exploitation of all its tributaries. The lowering started about four decades ago but geological hazards appeared more and more frequently from the end of the 1980s. The water level lowering is matched by a parallel groundwater level drop, which results in an increasing intensity of underground and surface water flow. The diagonal interface between the Dead Sea brine and the fresh groundwater is pushed downwards and seawards. Nowadays, sinkholes, subsidence, landslides and reactivated salt-karsts affect wide coastal segments. Until now, mainly infrastructures were damaged and few people/animals were injured, but the ongoing development of tourism in this very attractive situation will increase the risk if precautionary measures are not included in the development plans. This paper discusses the main observations made all around the Dead Sea and shed a light on the differences between the geological hazards of the western shore (Israel, Palestinian Authority) and the eastern shore (Jordan). It is the first attempt to bring together an overview of the human-induced geological hazards encountered along the Dead Sea coast.

Keywords

Dead Sea Sinkholes Subsidence Landslides 
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Notes

Acknowledgments

We thank David J. Lowe, Mario Paraise, and a third anonymous reviewer for their thorough reviews which improved this paper significantly. The research of Damien Closson is supported by the Royal Military Academy of Belgium and the NATO Science Programme/Cooperative Science and Technology Sub-Programme/Collaborative Linkage Grant n° 982884. The work of Najib Abou Karaki was partly supported by the European Community through the project APAME “Archaeoseismology and Paleoseismology for the protection of Cultural Heritage and Archaeological sites in the Middle East, The Impact of Large Earthquakes on Archaeological Sites and Cultural Heritage in the Middle East (Jordan, Lebanon, Syria, and Turkey)” ICA3-CT 2002-10024. The support of these parties is highly appreciated.

References

  1. Abelson M, Baer G, Shtivelman V, Wachs D, Raz E, Crouvi O, Kurzon I, Yechieli Y (2003) Collapse-sinkholes and radar interferometry reveal neotectonics concealed within the Dead Sea basin. Geophys Res Lett 30(10):52.1–52.4CrossRefGoogle Scholar
  2. Akawwi E (2006) Locating zones and quantify the submarine groundwater discharge into the Eastern shores of the Dead Sea, Jordan. Thesis, University of Göttingen, Germany, 188 ppGoogle Scholar
  3. Al-Zoubi A, ten Brink US (2001) Salt diapirs in the Dead Sea basin and their relationship to Quaternary extensional tectonics. Mar Petrol Geol 18(7):779–797CrossRefGoogle Scholar
  4. Al-Zoubi A, Abueladas AA, Al-Rzouq R, Camerlynck C, Akkawi E, Ezarsky M, Hamatteh A, Ali W, Rawashdeh S (2007) Use of 2D multi electrodes resistivity imagining for sinkholes hazard assessment along the eastern part of the Dead Sea, Jordan. Am J Environ Sci 3(4):229–233Google Scholar
  5. Arkin Y, Gilat A (2000) Dead Sea sinkholes—an ever-developing hazard. Environ Geol 39(7):711–722CrossRefGoogle Scholar
  6. Assaf KK, Ben-Zvi M, Clarke JS, El-Naser H, Kesslerm S, Landers MN, Nuseibeh MF, Wipperfurth CJ (1998) Overview of Middle East Water Resources. Water Resources of Palestinian, Jordanian, and Israeli Interest. Compiled by USGS for the EXACT Middle East Water Data Banks Project. US Geological Service, ISBN 0-607-91785-7. (http://water.usgs.gov/exact/overview/index.htm)
  7. Baer G, Schattner U, Wachs D, Sandwell D, Wdowinski S, Frydman S (2002) The lowest place on Earth is subsiding—an InSAR (Interferometric synthetic aperture radar) perspective. Geol Soc Am Bull 114(1):12–23CrossRefGoogle Scholar
  8. Bartov Y, Enzel Y, Stein M, Agnon A (2006) Late quaternary faulting and subsidence of the Dead Sea Basin. Israel J Earth Sci 55:17–31CrossRefGoogle Scholar
  9. Ben-Avraham Z (1997) Geophysical framework of the Dead Sea: structure and tectonics. In: Niemi TM, Ben-Avraham Z, Gat J (eds) The Dead Sea, the lake and its setting. Oxford University Press, Oxford, pp 22–35Google Scholar
  10. Ben-Avraham Z, Niemi T, Heim C, Negendank J, Nur A (1999) Holocene stratigraphy of the Dead Sea: correlation of high-resolution seismic reflection profiles to sediment cores. J Geophys Res 104:17617–17625CrossRefGoogle Scholar
  11. Bender F (1967) Map of “The salt upwarp of El Lisan”. Phillips Petrol Company, 1960/1961; Seismic Survey ARGAS, 1967; Drilling by Natural Resources Authorities, 1967/1968Google Scholar
  12. Bouwer H (1978) Groundwater hydrology. McGraw-Hill, New YorkGoogle Scholar
  13. Closson D (2005a) Structural control of sinkholes and subsidence hazards along the Jordanian Dead Sea Coast. Environ Geol 47(2):290–301CrossRefGoogle Scholar
  14. Closson D (2005b) Cooccurrence between the geo-hazards induced by the Dead Sea level lowering and the geological setting—Lisan Peninsula, Lynch Strait, Ghor Al Haditha—Jordan. Thesis, University of Liège, BelgiumGoogle Scholar
  15. Closson D, Abou Karaki N, Hansen H, Derauw D, Barbier C, Ozer A (2003a) Space-borne radar interferometric mapping of precursory deformations of a dyke collapse—Dead Sea Area—Jordan. Int J Remote Sens 24(4):843–849CrossRefGoogle Scholar
  16. Closson D, Abou Karaki N, Hussein MJ, Al-Fugha H, Ozer A, Mubarak A (2003b) Subsidence and sinkholes along the Jordanian Coast of the Dead Sea: contribution of gravimetry and radar differential interferometry. Compte Rendus Geosci 335(12):869–879CrossRefGoogle Scholar
  17. Closson D, Abou Karaki N, Klinger Y, Hussein MJ (2005) Subsidence hazards assessment in the Southern Dead Sea Area, Jordan. Pure Appl Geophys 162(2):221–248CrossRefGoogle Scholar
  18. Closson D, LaMoreaux PE, Abou Karaki N, al-Fugha H (2006) Karst system developed in salt layers of the Lisan Peninsula, Dead Sea, Jordan. Environ Geol 52(1):155–172CrossRefGoogle Scholar
  19. Derauw D (1999) Synthetic aperture radar phasimetry: theory and applications (Phasimétrie radar à synthèse d’ouverture: théorie et applications). Thesis, University of Liege, BelgiumGoogle Scholar
  20. El-Isa Z, Rimawi O, Jarrar G, Abou Karaki N, Taqieddin S, Atallah M, Abdelrahman N, Al Saed A (1995) Assessment of the hazard of subsidence and sinkholes in Ghor Al Haditha Area. Centre for Consultation, Technical Services and Studies, University of JordanGoogle Scholar
  21. Freund R, Garfunkel Z, Zak I, Goldberg M, Weisbrod T, Derin B (1970) The shear along the Dead Sea rift. Phil Trans R Soc Lond 267:107–130CrossRefGoogle Scholar
  22. Garfunkel Z, Zak I, Freund R (1981) Active faulting in the Dead Sea rift. Tectonophysics 80:1–26CrossRefGoogle Scholar
  23. Hubbert MK (1940) The theory of groundwater motion. J Geol 48:785–944CrossRefGoogle Scholar
  24. Itamar A, Reizmann Y (2000) Air photo survey of sinkholes in the Dead Sea area. Geol Surv Israel Curr Res 12:21–24Google Scholar
  25. Klein C (1985) Scientific basis for water resources management. M Diskin (ed) IAHS publication, 153, Oxford, UK, vol 2, pp 197–224Google Scholar
  26. Marschalk U, Bauer M, Pfeiffer B, Roth A, Hoffmann J, Rabus B (2004) Derivation of a multi-sensor interferometric DEM of the Dead Sea Region. In: Lacoste H, Ouwehand L (eds) Proceedings of the 2004 Envisat & ERS symposium (ESA SP-572). September 2004, Salzburg, pp 6–10Google Scholar
  27. Migowski C, Stein M, Prasad S, Negendank JFW, Agnon A (2006) Holocene climate variability and cultural evolution in the Near East from the Dead Sea sedimentary record. Q Res 66(3):421–431CrossRefGoogle Scholar
  28. Quennell A (1958) The structural and geomorphic evolution of the Dead Sea Rift. Q J Geol Soc Lond 114:1–24CrossRefGoogle Scholar
  29. Rybakov M, Rotstein Y, Shirman B, Al-Zoubi A (2005) Cave detection near the Dead Sea—a micromagnetic feasibility study. Leading Edge 24(6):585–590CrossRefGoogle Scholar
  30. Royal Haskoning Newletter (2005) International version 3(3):2Google Scholar
  31. Salameh E, El-Naser H (1999) Does the actual drop in Dead Sea level reflect the development of water sources within its drainage basin? Acta Hydrochem et Hydrobiol 27:5–11CrossRefGoogle Scholar
  32. Salameh E, El-Naser H (2000a) Changes in the Dead Sea level and their impact on the surrounding groundwater bodies. Acta Hydrochimi et Hydrobiol 28:24–33CrossRefGoogle Scholar
  33. Salameh E, El-Naser H (2000b) The interface configuration of the Fresh-/Dead Sea water—theory and measurements. Acta Hydrochim et Hydrobiol 28:323–328CrossRefGoogle Scholar
  34. Salameh E, Farajat M (2006) The role of volcanic eruptions in blocking the drainage leading to the Dead Sea formation. Environ Geol 52(5):519–527Google Scholar
  35. Shalev E, Lyakhovsky V, Yechieli Y (2006) Salt dissolution and sinkhole formation along the Dead Sea shore. J Geophys Res 111:BO3102CrossRefGoogle Scholar
  36. Shimoni M, Hanssen RF, Van Der Meer F, Kampes BM, Ben Dor E (2002) Salt Diapir movements Using SAR interferometry in the Lisan Peninsula, Dead Sea Rift. Proc SPIE 4543:151–160CrossRefGoogle Scholar
  37. Taqieddin SA, Abderahman NS, Atallah M (2000) Sinkhole hazards along the Eastern Dead Sea shoreline area, Jordan: a geological and geotechnical consideration. Environ Geol 39(11):1237–1253CrossRefGoogle Scholar
  38. Yechieli Y, Magaritz M, Levy Y, Weber U, Kafri U, Woelfli W, Bonami G (1993) Late quaternary geological history of the Dead Sea area, Israel. Q Res 39:59–67CrossRefGoogle Scholar
  39. Yechieli Y, Wachs D, Abelson M, Crouvi O, Shtivelman V, Raz E, Baer G (2002) Formation of sinkholes along the shore of the Dead Sea—summary of the first stage of investigation. In: Beck BF (ed) Sinkholes and the engineering and environmental impacts of karst. Huntsville, Alabama, pp 184–194Google Scholar
  40. Yechieli Y, Abelson M, Bein A, Crouvi O (2006) Sinkholes “swarns” along the Dead Sea coast: reflection of disturbance of lake and adjacent groundwater systems. GSA Bull 118(9/10):1075–1087CrossRefGoogle Scholar
  41. Zak I (1967) The Geology of Mount Sedom. Ph.D. thesis, The Hebrew University, JerusalemGoogle Scholar

Copyright information

© Springer-Verlag 2008

Authors and Affiliations

  1. 1.Royal Military AcademySignal and Image CentreBrusselsBelgium
  2. 2.Environmental and Applied Geology DepartmentUniversity of JordanAmmanJordan

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