Evaluation of Groundwater and Seawater Intrusion at Tajoura Area, Northwest Libya
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Evaluation of Groundwater and Seawater Intrusion at Tajoura Area, Northwest Libya

Authors: Abdalraheem Huwaysh, Yasmin ElAhmar

Abstract:

Water quality is an important factor that determines its usage for domestic, agricultural and industrial uses. This study was carried out through the Tajoura Area, Jifarah Plain, Northwest Libya. Chemical and physical parameters were measured and analyzed for groundwater samples collected in 2021 from 26 wells distributed throughout the investigation area. Overexploitation of groundwater caused considerable deterioration in the water quality, especially at Tajoura Town (20 km east of Tripoli). The aquifer shows an increase in salinization, which has reached an alarming level in many places during the past 25 years as a result of the seawater intrusion. Based on the WHO and Libyan standards, groundwater from the targeted area was not suitable for direct drinking purposes. Sodium is the dominant cation, while the dominant anion is chloride. Based on the Piper trilinear diagram, most of the groundwater samples (90%) were identified as sodium chloride type. The best groundwater quality exists at the southern part of the study area. Serious degradation in the water quality, expressed in salinity increase, occurs as we go towards the coastline. The abundance of NaCl waters is strong evidence to attribute the successive deterioration of the water quality to the seawater intrusion. Considering the values of Cl- concentration and the ratio of Cl-/HCO3-, about 70% of the groundwater samples were strongly affected by the saline water. Car wash stations in the study area as well as the unlined disposal pond used for the collection of untreated wastewaters, contribute significantly to the deterioration of water quality. In the area of interest (Tajoura), treatment of the groundwater before drinking is essential, and its quality needs to be routinely checked.

Keywords: Tajoura, groundwater, overexploitation, seawater intrusion.

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References:


[1] Nawal al Farrah, Kristine Martens & Kristine Walraevens, 2011, Hydrochemistry of the Upper Miocene-Pliocene-Quaternary Aquifer Complex of Jifarah Plain, Nw-Libya. Geologica Belgica (2011) 14/3- 4:159
[2] Nawal Alfarrah and Kristine Walraevens, 2018, Groundwater Overexploitation and Seawater Intrusion in Coastal Areas of Arid and Semi-Arid Regions, Water 2018, 10, 143; doi:10.3390/w10020143
[3] Wheida, E. (2012). The Water resources management in Libya, Libyan Agriculture Research Center Journal International, vol. no 3 (3), 144- 154.
[4] General Water Authority (GWA). 1999-2003. Piezometric network reports. Unpublished reports. Western branch. GWA. Tripoli. Libya.
[5] Pallas, P. (1980). Water Resources of the Socialist People’s Libyan Arab Jamahirya. In: The Geology of Libya, volume II, Second Symposium on the Geology of Libya. 16 -21 September, 1978, (eds. M. J. Salem and M.T. Busrewil), Academic Press, London, 539-594.
[6] Baruni.S.S, 2015, Water Situation in Libya, Earth Science Society of Libya (ESSL), Proceeding of the National Water Conference, PP 71-100.
[7] Todd, D. K. (2005). Groundwater hydrology. 3rd Ed., John Willy and Sons, New York, 652 p.
[8] Boyd, C.E. (2000) Water Quality an Introduction. Kluwer Academic Publisher, USA, 330 p.
[9] Hem, J.D. (1985) Study and Interpretation of the Chemical Characteristics of Natural Water. 3rd Edition, US Geological Survey Water-Supply Paper 2254, University of Virginia, Charlottesville, 263 p.
[10] Detay, M. (1997) Water Wells-Implementation, Maintenance and Restoration. John Wiley and Sons, London, 379 p.
[11] Drever, J.I. (1997) The Geochemistry of Natural Water: Surface and Groundwater Environments. 3rd Edition, Prentice Hall, New Jersey.
[12] Fetter, C.W. (1980). Applied Hydrogeology, Charles E. Merrill Publishing Co, Ohio, 488 p.
[13] WHO (World Health Organization). (1984). Guidelines for drinkingwater quality. Vol. 2. Health criteria and other supporting information, Geneva, 717 p.
[14] Sawyer, C., & McCARTY, P. (1967). Chemistry for sanitary engineers. McGraw-Hill, New York.
[15] Piper, A.M. (1994) A graphic procedure in the geochemical interpretation of water analyses. Am. Geophys. Union Trans.v.25, pp.914-923
[16] WHO (World Health Organization). (2011). Guidelines for drinkingwater quality. fourth edition.