Abstract
The quality and geochemistry of groundwater are significantly affected by the depositional environment of aquifer sediments. Miocene sediments in Al Wahat area (Jalu, Awjilah and Shakherah Oases) in the Libyan Desert at the north-east of the country have been deposited in fluvial marginal marine and marine environments. The purposes of this paper are to describe the areal distribution of the dominant water quality constituents, to identify the major hydro-geochemical processes that affect the quality of water and to evaluate the relations of sedimentary depositional environments and groundwater flow to the quality and geochemistry of water in aquifer sediments of Post-Eocene. This study is the first investigation in Al Wahat Oasis and also in the whole Sahara, which introduces the importance of considering the end members and the synsedimentary influence for the interpretation of the aquifer hydrochemistry. The area involved in this study is within the boundaries 28°N–30°N and 21°E–23°E. Eighteen wells are selected in the area, including eight piezometers, and ten samples were analysed from wells used for domestic and agricultural purposes. Results show high and significant increase in total dissolved solids, especially Na+, Cl−, SO4 2− and NO3 − compared with the previous years. The chemical results for the groundwater samples in Al Wahat are classified according to the Stuyfzand groundwater classification system; the water type is mostly brackish and brackish-saline NaCl in the downstream direction and fresh-brackish NaHCO3 upstream. These water types indicate that groundwater chemistry is changed by cation exchange reactions during flushing of the diluted saline aquifer by freshwater from the south. The different stages of cation exchange produce a chromatographic sequence of groundwater types. These cation exchange reactions during the freshening process occur mainly in the intercalated clay, resulting in a Na+ increase, and peaks of K+ and Mg2+ in the aquifer. In the north, the synsedimentary marine influence on the groundwater is stronger and the abstraction for irrigation is higher. Upconing of deep saline water and anthropogenic pollution may contribute significantly to the aquifer water quality. Calcite equilibrium and gypsum dissolution are also important hydrochemical processes in the aquifer.
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References
Ahmad MU (1983) A quantitative model to predict safe yield for wellfield in the Kufra and Sarir Basins, Libya. Ground Water 21(1):58–66
Alfarrah N (2011) Hydrogeological and hydrogeochemical investigation of the coastal area of Jifarah Plain, NW Libya. Ph.D. thesis, Laboratory of Applied Geology and Hydrogeology, Ghent University, Belgium
Alfarrah N, Martens K, Walraevens K (2011) Hydrochemistry of the Upper Miocene-Pliocene-Quaternary aquifer complex of Jifarah Plain, NW-Libya. Geol Belgica 14(3–4):159–174
Alfarrah N, Van Camp M, Walraevens K (2013) Deducing transmissivity from specific capacity in the heterogeneous upper aquifer system of Jifarah Plain, NW-Libya. J Afr Earth Sci 85:12–21
Alfarrah N, Hweesh A, Berhane G, Walraevens K (2016) Groundwater quality assessment, hydrochemical characteristics and flow regime of the nubian aquifer system in tazerbo wellfield at the south-east of Libya. Hydrogeol (submitted)
Ambrose G (2000) The geology and hydrocarbon habitat of the Sarir Sandstone, SE Sirt Basin, Libya. J Petrol Geol 23(2):165–191
Appelo CAJ (1994) Cation and proton exchange, pH variations, and carbonate reactions in a freshening aquifer. Water Resour Res 30:2793–2805
Appelo CAJ, Postma D (1993) Geochemistry, groundwater and pollution. A.A. Balkema, Brookfield
Appelo CAJ, Willemsen A (1987) Geochemical calculations and observations on salt water intrusions. 1. A combined geochemical/mixing cell model. J Hydrol 94:313–330
Back WW (1966) Hydrochemical facies and ground-water flow patterns in northern part of Atlantic Coastal Plain: U.S. Geological Survey Professional Paper, 498-A
Baird DW, Aburawi RM, Bailey NJL (1996) Geohistory and petroleum in the central Sirt Basin. In: Salem MJ, El-Hawat AS, Sbeta AM (eds) The geology of Sirte Basin, vol 3. Elsevier, Amsterdam, pp 3–56
Ball J (1927) Problems of the Libyan Desert. Geogr J 70(1):21–38
Beekman HE (1991) Ion chromatography of fresh- and seawater intrusion. Ph.D. thesis, Free University, Amsterdam
Blaser PC, Kipfer K, Loosli HH, Walraevens K, Van Camp M, Aeschbach-Hertig M (2010) A 40 ka record of temperature and permafrost conditions in northwestern Europe from noble gases in the Ledo-Paniselian Aquifer, Belgium
Cardenal J, Walraevens K (1994) Chromatographic pattern in a freshening aquifer (Tertiary Ledo-Paniselian aquifer, Flanders-Belgium). Min Mag 58A:146–147
Chapelle FH, Knobel LL (1983) Aqueous geochemistry and exchangeable cation composition of glauconite in the Aquia aquifer, Maryland. Ground Water 21:343–352
Coetsiers M, Walraevens K (2006) Chemical characterization of the Neogene Aquifer, Belgium. Hydrogeol J 14:1556–1568
Da’as A, Walraevens K (2010). Groundwater salinity in Jericho Area, West Bank, Palestine. SWIM-21 Salt Water Intrusion Meeting, Ponta Delgada, San Miguel, Azores, Portugal. In: Proceedings, pp 28–31
De Menocal P, Ortiz J, Guilderson T, Adkins J, Sarnthein M, Baker L, Yarusinsky M (2000) Abrupt onset and termination of the African humid period: rapid climate responses to gradual insolation forcing. Quat Sci Rev 19(1–5):347–361
Elakkari TS (2005) Structural configuration of the sirt basin. ITC, Enschede, Netherlands
Ezzat A (1959) Ecological studies of bottom living Amphipods in the Nozha Hydrodrome. Editing and Publication Section, Extension Department, Egypt
Faitouri M (2013) Isotope and noble gas study of three aquifers in central and eastern Libya. Ph.D. Thesis, Colorado State University, USA
Faitouri M, Sanford WE (2015) Stable and radio-isotope analysis to determine recharge timing and paleoclimate of sandstone aquifers in central and southeast Libya. Hydrogeol J. doi:10.1007/s10040-015-1232-7
Fidelibus MD, Gimenez E, Morell I, Tulipano L (1993) Salinization processes in the Castellon plain aquifer (Spain). In: Custodio and Galofre (eds) Study and modelling of saltwater intrusion into aquifers. 12th Salt water intrusion meeting, Barcelona, Nov 1992. CIHS, CIMNE, Barcelona, pp 267–283
Foster MD (1950) The origin of high sodium bicarbonate waters in the Atlantic and Gulf coastal plains. Geochim Cosmochim Acta 1:33–48
Gabert G, Kleinsorge H, Kreysing K, Venzlaff H (1961) Some results of ground water investigations in the republic of Sudan. In: Symposium of Athens. IASH Publication, number 56, pp 201–213
General Water Authority (GWA) (2006) General water authority. Unpublished report
General Water Authority (GWA) (2014) General water authority. Unpublished report
Gossel W, Ebraheem AM, Wycisk P (2004) A very large scale GIS-based groundwater flow model for the Nubian sandstone aquifer in Eastern Sahara (Egypt, northern Sudan and eastern Libya). Hydrogeol J 12:698–713
Gras R, Thusu B (1998) Trap architecture of the Early Cretaceous Sarir Sandstone in the eastern Sirte Basin, Libya. In: Macgregor SD, Moody JTR, Clark-Lowes DD (eds) Petroleum geology of North Africa: Geological Society (London) Special Publication 132, pp 317–334
Gumati YD, Kanes WH (1985) Early tertiary subsidence and sedimentary facies-Northern Sirte Basin, Libya. Am Assoc Petrol Geol Bull 69:39–52
Gumati YD, Nairn AEM (1991) Tectonic subsidence of the Sirte Basin, Libya. J Petrol Geol 14:93–102
Harding TP (1984) Graben hydrocarbon occurrences and structural style. AAPG Bull 68(3):333–362
Jones BF, Vengosh A, Rosenthal E, Yechieli Y (1999) Geochemical investigations. In: Seawater intrusion in coastal aquifers: concepts, methods, and practices. Kluwer, Dordrecht, The Netherlands, pp 51–71
Kroner A (1993) The Pan-African belt of north-eastern and eastern Africa, Madagascar, southern India, Sri Lanka and east Antarctica; Terrane amalgamation during formation of the Gondwana Supercontinent. In: Thorwiehe U, Schandelmeier H (eds) Geo-scientific research in Northeast Africa. A.A. Balkema, Rotterdam, pp 3–9
Lawrence AR, Lloyd JW, Marsh JM (1976) Hydrochemistry and ground-water mixing in part of the lincolnshire limestone aquifer, England. Groundw 14:320–327
Mohamed C, Zineb A (2015) Geochemistry and hydrogeochemical process of groundwater in the Souf valley of Low Septentrional Sahara. Algeria 9(3):261–273
Pallas P (1981) Water Resources of the Socialist People’s Libyan Arab Jamahiriya. In: Salem MJ, Busrewil MT (eds) Geology of Libya. Academic Press, London, pp 539–594
Pallas P, Salem O (2000) Water resources utilization and management of the Socialist Peoples Arab Jamahiriya. In: Regional management of aquifer systems in arid zones: managing non-renewable resources. Proceedings of Tripoli Conference, 1999, UNESCO, Paris, pp 147–172
Parkhurst DL, Appelo CAJ (1999) User’s guide to PHREEQC (Version 2), A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations. U.S. Geological Survey, USA
Pim R, Binsariti A (1994) The Libyan great man-made river project. Paper 2. The water resource. Proc ICE-Water Maritime Energy 106(2):123–145
Richter BC, Kreitler CW (1993) Geochemical techniques for identifying sources of groundwater salinization. C.K. Smoley, Boca Raton
Salem O, Pallas P (2002) The Nubian Sandstone Aquifer System (NSAS). In: Applegren B (ed) Managing shared aquifer resources in Africa Paris: United Nations Educational, Scientific and Cultural Organization (IHP-VI Series on groundwater 8), pp 19–21
Sandford K (1935) Geological observations on the northwest frontiers of the anglo-Egyptian Sudan and the adjoining part of the southern Libyan Desert. Q J Geol Soc 91(1–4):323–381
Schroter T (1996) Tectonic and sedimentary development of the central Zallah Trough (west Sirt Basin, Libya). In: Salem MJ, Busrewil MT, Misallati AA, Sola MJ (eds) First symposium on the sedimentary basins of Libya, geology of the Sirt Basin, vol 3. Elsevier, Amsterdam, pp 123–136
Sonntag I, Schwarz H, Hirota Y, Henning U (1978) Cell envelope and shape of Escherichia coli: multiple mutants missing the outer membrane lipoprotein and other major outer membrane proteins. J Bacteriol 136:280–285
Stuyfzand PJ (1986) A new hydrogeochemical classification of water types: principles and application to the coastal dunes aquifer system of the Netherlands. In: Proceedings 9th Salt Water Intrusion Meeting (SWIM), Delft, The Netherlands, pp 641–656
Stuyfzand PJ (1993) Hydrochemistry and hydrology of the coastal dune area of the western Netherlands. Ph.D. dissertation, Free University (VU), Amsterdam, 90-74741-01-0: 366
Sultan M, Sturchio N, Hassan FA, Hamdan MAR, Mahmood AM, El Alfy Z, Stein T (1997) Precipitation source inferred from stable isotopic composition of Pleistocene groundwater and carbonate deposits in the Western Desert of Egypt. Quat Geol 4:29–37
Van der Meer F, Cloetingh S (1993) Intraplate stresses and subsidence history of the sirte basin (Libya). Tectonophys 226:37–58
Voss CI, Soliman SM (2014) The transboundary non-renewable Nubian Aquifer System of Chad Egypt, Libya and Sudan: classical groundwater questions and parsimonious hydrogeologic analysis and modeling. Hydrogeol J 22:441–468
Walraevens K (1987) Hydrogeology and hydrochemistry of the Ledo-Paniselian in Eastern and Western Flanders (in Dutch). 350 p. + fig. + annexes. Ph.D. Dissertation, Ghent University
Walraevens K (1990) Hydrogeology and hydrochemistry of the Ledo-Paniseliaan semi-confined aquifer in East- and West-Flanders. Academiae Analecta 52, pp 12–66
Walraevens K, Cardenal J (1994) Aquifer recharge and exchangeable cations in a tertiary clay layer (Bartonian clay, Flanders-Belgium). Mineral Mag 58A, pp 955–956
Walraevens K, Van Camp M (2005) Advances in understanding natural groundwater quality controls in coastal aquifers. In: 18 Salt Water Intrusion Meeting (SWIM). Cartagena 2004, Spain, pp 451–460
Walraevens K, Boughriba M, De Breuck W (1993) Groundwater quality evolution in the black–sluice polder area around assenede (Belgium). In: Custodio E, Galofre A (eds) Study and modelling of saltwater intrusion into aquifers. 12th salt water intrusion meeting, Barcelona, Nov 1992. CIHS. CIMNE, Barcelona, pp 121–142
Walraevens K, Cardenal-Escarcena J, Van Camp M (2007) Reaction transport modelling of a freshening aquifer (Tertiary Ledo-Paniselian Aquifer, Flanders-Belgium). Appl Geochem 22:289–305
Walraevens K, Ibrahimu CM, Yohana M, Van Camp M (2015) Sources of salinity and urban pollution in the Quaternary sand aquifers of Dar es Salaam, Tanzania. J Afr Earth Sci 102:149–165
WHO (2008) Guidelines for drinking-water quality (electronic resource): incorporating 1st and 2nd addenda, vol 1, recommendations, 3rd edn. WHO Library Cataloguing-in-Publication Data
Wright EP, Edmunds WM (1971) Hydrogeological studies in central Cyrenaica. Symposium on the geology of libya. University of Libya, Tripoli, pp 459–481
Wright EP et al (1974) Jalu-Tazerbo Project: phase I final report. Institute of geological sciences, London (unpublished)
Wright EP, Benfield AC, Edmunds WM, Kitching R (1982) Hydrogeology of the Kufra and Sirte Basins, eastern Libya. Q J Eng Geol 15:83–103
Yüce G (2005) Determination of the recharge area and salinization degree of Karst Springs in the Lamas Basin (Turkey). Isot Environ Health Stud 41(4):391–404
Acknowledgments
The authors greatly thank the General Water Authority, Tripoli, Libya, for collaboration in collecting data and all who supported in this study. The authors are grateful to Prof. Galip Yüce for his constructive comments, allowing to improve the manuscript.
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Alfarrah, N., Hweesh, A., van Camp, M. et al. Groundwater flow and chemistry of the oases of Al Wahat, NE Libya. Environ Earth Sci 75, 985 (2016). https://doi.org/10.1007/s12665-016-5796-x
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DOI: https://doi.org/10.1007/s12665-016-5796-x