TY - JOUR
T1 - Multi-disciplinary modeling, in stratigraphy and groundwater stratigraphy of the Jordan River basin
AU - Anker, Yaakov
AU - Rosenthal, Eliahu
AU - Shulman, Haim
AU - Flexer, Akiva
N1 - Funding Information:
Acknowledgments The authors would like to express his thanks to the German Ministry of Education and Research (BMBF) and to the Israeli Ministry of Science (MOS) for supporting and funding the project: Water Resources Evaluation for a Sustainable Development in the Jordan Rift Basin, German–Israeli–Palestinian Joint Research Program, Project Number 2WT 9179/1773 which the present study is part of. Many thanks are due to the Israeli Water Commission, for supporting the sampling process and analysis. Thanks are due to the staff of the Institute of Earth Sciences of the Hebrew University and to Prof Abraham Starinsky for illuminating some of the geochemical processes. The staff of FZU Leipzig-Halle for helping with the stable isotopes. The Göttingen University, for assisting with the strontium isotopes analysis. The staff of the Karlsruhe University, AGK, for assisting with additional chemical analysis and Dr Josef Guttman. Mekorot-the Israeli Water Company for supplying up-to-date figures of the water wells in the region. Finally, we wish to show gratitude to ProfDrHüseyinGÖKC¸EKUS¸ theeditorofthisspecialissueandthe anonymous reviewer for their uppermost attention.
PY - 2009/3
Y1 - 2009/3
N2 - The study area is located along the Dead Sea Rift, the climate is considered arid in its southern margin near the Dead Sea, which is the lowest water reservoir found on the globe (412 m BSL), to semiarid in its northern part. During the last few decades, the water resources became depleted limiting the natural development of the agricultural settlements, which are the most common type of communities in the region. Previous studies suggested that a large amount of freshwater is lost as the result of salinization processes, which occur when fresh groundwater from the mountain aquifers, flow into the saline clastic Neogene aquifer complex. In order to comprehend this complex system, a detailed outlining of the regional hydrogeological system is essential. Since there are no boreholes, which penetrate the aquiferous rock sequences within the Rift, it was necessary to interpolate a large variety of data from several fields of geosciences. The methods applied included geological mapping, geophysical modeling based on interpretation of seismic profiles and geochemical modeling based on chemical and isotopic analysis of runoff, sediments and groundwater. The combined modeling based on results from the different types of analyses implied to several conclusions relevant to the regional water management policy: (1) groundwater becomes saline as it flows from the margins of the Rift to its center. Therefore, it is recommended to exploit it along the foothills of the rift escarpment. (2) Geophysical modeling indicated that the foothills and the Karstic mountain aquifer extend into the subsurface of the valley and can be farther exploited (up to 15 mm3 per annum) by relatively shallow wells. (3) Several mechanisms of groundwater salinization were deciphered: (a) the dense vertical faulting systems act as potential conduits for saline water, which flow-up from deep-seated sources and penetrate into the fresh aquifers. (b) Fresh groundwater in the clastic aquifer complex is rare, furthermore, two evaporates bodies were encountered (Auja and Zaharat el Qurein), also acting as sources for fresh water salinization. (c) Although the quantity of runoff recharge to the Jordan Valley aquifer complex is negligible, the increase in its salt-content (TDS) turns this negligible freshwater recharge to a significant contributor of salts.
AB - The study area is located along the Dead Sea Rift, the climate is considered arid in its southern margin near the Dead Sea, which is the lowest water reservoir found on the globe (412 m BSL), to semiarid in its northern part. During the last few decades, the water resources became depleted limiting the natural development of the agricultural settlements, which are the most common type of communities in the region. Previous studies suggested that a large amount of freshwater is lost as the result of salinization processes, which occur when fresh groundwater from the mountain aquifers, flow into the saline clastic Neogene aquifer complex. In order to comprehend this complex system, a detailed outlining of the regional hydrogeological system is essential. Since there are no boreholes, which penetrate the aquiferous rock sequences within the Rift, it was necessary to interpolate a large variety of data from several fields of geosciences. The methods applied included geological mapping, geophysical modeling based on interpretation of seismic profiles and geochemical modeling based on chemical and isotopic analysis of runoff, sediments and groundwater. The combined modeling based on results from the different types of analyses implied to several conclusions relevant to the regional water management policy: (1) groundwater becomes saline as it flows from the margins of the Rift to its center. Therefore, it is recommended to exploit it along the foothills of the rift escarpment. (2) Geophysical modeling indicated that the foothills and the Karstic mountain aquifer extend into the subsurface of the valley and can be farther exploited (up to 15 mm3 per annum) by relatively shallow wells. (3) Several mechanisms of groundwater salinization were deciphered: (a) the dense vertical faulting systems act as potential conduits for saline water, which flow-up from deep-seated sources and penetrate into the fresh aquifers. (b) Fresh groundwater in the clastic aquifer complex is rare, furthermore, two evaporates bodies were encountered (Auja and Zaharat el Qurein), also acting as sources for fresh water salinization. (c) Although the quantity of runoff recharge to the Jordan Valley aquifer complex is negligible, the increase in its salt-content (TDS) turns this negligible freshwater recharge to a significant contributor of salts.
KW - Ground water
KW - Hydrogeology
KW - Water resources
UR - http://www.scopus.com/inward/record.url?scp=60549107049&partnerID=8YFLogxK
U2 - 10.1007/s00254-008-1335-8
DO - 10.1007/s00254-008-1335-8
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AN - SCOPUS:60549107049
SN - 0943-0105
VL - 57
SP - 275
EP - 283
JO - Environmental Geology
JF - Environmental Geology
IS - 2
ER -