Abstract
The spatial and temporal changes of the composition of the groundwater from the springs along the Wadi Qilt stream running from the Jerusalem–Ramallah Mountains towards the Jericho Plain is studied during the hydrological year 2006/2007. The residence time and the intensity of recharge play an important role in controlling the chemical composition of spring water which mainly depends on distance from the main recharge area. A very important factor is the oxidation of organics derived from sewage and garbage resulting in variable dissolved CO2 and associated HCO3 − concentration. High CO2 yields lower pH values and thus under-saturation with respect to calcite and dolomite. Low CO2 concentrations result in over-saturation. Only at the beginning and at the end of the rainy season calcite saturation is achieved. The degradation of dissolved organic matter is a major source for increasing water hardness. Besides dissolution of carbonates dissolved species such as nitrate, chloride, and sulfate are leached from soil and aquifer rocks together with only small amounts of Mg. Mg not only originates from carbonates but also from Mg–Cl waters are leached from aquifer rocks. Leaching of Mg–Cl brines is particularly high at the beginning of the winter season and lowest at its end. Two zones of recharge are distinguishable. Zone 1 represented by Ein Fara and Ein Qilt is fed directly through the infiltration of meteoric water and surface runoff from the mountains along the eastern mountain slopes with little groundwater residence time and high flow rate. The second zone is near the western border of Jericho at the foothills, which is mainly fed by the under-groundwater flow from the eastern slopes with low surface infiltration rate. This zone shows higher groundwater residence time and slower flow rate than zone 1. Groundwater residence time and the flow rate within the aquifer systems are controlled by the geological structure of the aquifer, the amount of active recharge to the aquifer, and the recharge mechanism. The results of this study may be useful in increasing the efficiency of freshwater exploitation in the region. Some precautions, however, should be taken in future plans of artificial recharge of the aquifers or surface-water harvesting in the Wadi. Because of evaporation and associated groundwater deterioration, the runoff water should be artificially infiltrated in zones of Wadis with high storage capacity of aquifers. Natural infiltration along the Wadis lead to evaporation losses and less quality of groundwater.
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References
Arad A, Michaeli A (1967) Hydrogeological investigations in the western catchment area of the Dead Sea. Isr J Earth Sci 16:181–196
ARIJ (1997) Water Resources. In: The Status of the environment in the West Bank. ARIJ, Jerusalem, pp 95–107
Arkin Y (1976) Explanations to the geological map of the Jerusalem- Bet Shemesh area. Isr J Earth Sci 16:46–47
Bakalowicz M (1979) The Role and contribution of Geochemistry to investigate the Karstic Aquifer and Karstification. Ph.D. Thesis, University of Paris VI
Begin ZB (1974) Geological Map of Israel, Jericho, Sheet 9-III, 1:50,000, with explanatory notes—Geology Survey of Israel, Jerusalem
Bullen TD, Krabbenhoft DP, Kendall C (1996) Kinetic and mineralogic controls on the evolution of groundwater chemistry and 87[Sr]/86[Sr] in a sandy silicate aquifer, northern Wisconsin. Geochim Cosmochim Acta 60:1807–1821
Edmunds WM, Smedley PL (2000) Residence time indicators in groundwater: the East Midlands Triassic sandstone aquifer. Appl Geochem 15:737–752
Flexer A, Gilat A, Hirsch F, Honigstein A, Rosenfeld A, Rueffer T (1989) Late Cretaceous evolution of the Judean Mountains as indicated by ostracods. Terra Nova 1:349–358
Guttman J (1997) The hydrogeological conditions in the Cenomanian Aquifer along the margins of the Jordan Valley (the Fazael–Auja–Jericho area). Tel Aviv, Tahal (01/79/26), pp 1–43
Guttman J (2000) GIJP Multi-lateral Project B: hydrogeology of the Eastern Aquifer in the Judea Hills and Jordan Valley. Mekorot Water Company, Report 468, pp 1–36
Guttman J (2004) The karstic flow system in Auja area—West Bank: an example of two separated flow system in the same area. The IPCRI 2nd Israeli–Palestinian Internal Conference Water for Life in the Midle East, Antalya, Turkey (October 2004)
IPCRI (1993) A proposal for the development of a regional water master plan, Israel/Palestine Center for Research Information, Jerusalem. Water in Palestine, Tunis (1990), pp 106–306
Kloppmann W, Dever L, Edmunds WM (1998) Residence time of chalk groundwaters in the Paris Basin and the North German Basin: a geochemical approach. Appl Geochem 13:593–606
Kroitoru L (1987) The characterization of flow systems in carbonatic rocks defined by the groundwater parameters: Central Israel; Ph.D. Thesis for the Weizman Institute of Science. Rehovot, Israel, pp 1–120
Kroitoru L Mazor E, Dror G (1985) Hydrological characteristic of the Wadi Kelt and Elisha springs. In: Scientific basis for water resources managment vol 153. IAHS Publication, Wallingford, pp 207–218
Langmuir D (1971) The Geochemistry of some carbonate groundwaters in Central Pennsylvania. Geochim Cosmochim Acta 35:1023–1045
Marie A, Vengosh A (2001) Sources of salinity in groundwater from Jericho area, Jordan Valley. Groundwater 39:240–248
Musgrove M, Banner J (2004) Controls on the spatial and temporal variability of vadose dripwater geochemistry: Edwards aquifer, central Texas. Geochem Cosmochim Acta 68:1007–1020
Qannam Z, Merkel B (2002) Hydrogeology, hydrochemistry and contamination sources in Wadi Al Arroub drainage basin, Palestine. Freiberger Forschungshefte—selected contribution to applied geology in the Jordan Rift Valley, C 494, Technische Universität Bergakademie Freiberg, Germany. ISBN: 3-86012-162-6, pp 111–123
Rofe & Raffety Consulting Engineers (1963) Geological and hydrological report, Jerusalem and district water supply—Hashemite Kingdom of Jordan, Central Water Authority, pp 1–79
Rosenthal E (1987) Chemical composition of rainfall and groundwater in recharge areas of the Bet Shean-Harod multiple aquifer system, Israel. J Hydrol 89:329–352
Roth I (1969) The geology of the Wadi el Qilt region, M. Sc. Thesis, Hebrew University Jerusalem, Israel, pp 1–52
Schoeller H (1977) Geochemistry of groundwater. In: Groundwater studies—an International guide for research and practice, UNESCO, Paris, Chap 15, pp 1–18
Tahal (1990) Water master plan. Report on the water sector Israel, Tahal Consulting Engineers Ltd (in Hebrew)
Toll M (2001) Hydrogeological characterization of the Uppermost Aquifer in the Wadi el Qilt Area, Diploma Thesis. Depart. Applied Geology, Tübingen University, Tübingen, Germany, pp 1–137
Wolfer J (1998) Hydrogeological investigation along the Jerusalem—Jericho Transect (Wadi el Qilt), West Bank/Israel, Diploma Thesis, Depart Applied Geology, Karlsruhe University, Karlsruhe, Germany, pp 1–106
Acknowledgments
The authors would like to thank the DAAD-German Academic Exchange Service and the DFG-German Research Foundation for the financial support of the project KH215/1-1. Finally, we gratefully thank the co-workers of the Hydrogeology Section in the UFZ-Helmholtz Centre for Environmental Research, (Dr. Marion Martienssen, Silke Koehler and Stefen Juergen) for their cooperation in data processing and sample measurements.
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Khayat, S., Möller, P., Geyer, S. et al. Hydrochemical variation in the springs water between Jerusalem–Ramallah Mountains and Jericho Fault, Palestine. Environ Geol 57, 1739–1751 (2009). https://doi.org/10.1007/s00254-008-1459-x
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DOI: https://doi.org/10.1007/s00254-008-1459-x