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Assessment and Mapping of Groundwater Quality for Irrigation and Drinking in a Semi-Arid Area in Algeria

Treść / Zawartość
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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Groundwater is the main resource used to meet the people’s drinking water and irrigation needs of the Ain Oussera plain, because of the lack of surface-water resources. This paper intended to evaluate the suitability of groundwater for agriculture and drinking in the Ain Oussera plains. The data of the study were gathered and analyzed from twenty (20) groundwater samples collected to assess the plain groundwater quality, using the Water Quality Index (WQI) and GIS, carried out on physico-chemical parameters, including potential of hydrogen (pH), total dissolved solids (TDS) electrical conductivity (EC), potassium (K+), sodium (Na+), magnesium (Mg2+), and calcium (Ca2+) and major anions (Cl, HCO3, NO3, SO4), as well as, the water suitability test for agricultural purposes, using the sodium adsorption ratio. These parameters were inserted into the GIS platform to create a spatial distribution map for each parameter using the inverse interpolation technique (IDW). The results indicated that the concentrations are within the Algerian permissible limits. The water quality index (WQI), which evaluates the suitability of water for consumption, varies from 31 to 173 with an average value of 81. 70% of the samples from the Ain Oussera plain fall within the excellent and good quality categories. Its water is suitable for consumption (WQI < 100), while 30% is in the poor water category. From the calculation of SAR values, it was found that 90% of the groundwater samples are considered excellent and suitable for irrigation. According to the classification of the United States Salinity Laboratory USSL, the Ain Oussera water quality is classified as poor for irrigation purposes.
Rocznik
Strony
19--32
Opis fizyczny
Bibliogr. 42 poz., rys., tab.
Twórcy
  • Department of Civil Engineering and Hydraulic, Ziane Achour University of Djelfa, Djelfa 17000, PO Box 3117, Algeria
  • Laboratoire des Réservoirs Souterrains: Pétroliers, Gaziers et Aquifères, Université Kasdi Merbah Ouargla, 30000, Algeria
autor
  • Earth & Univers Sciences Departement, Ziane Achour University of Djelfa. Djelfa 17000, PO Box 3117, Algeria
  • Laboratoire de Géologie de Sahara, Université Kasdi Merbah Ouargla, 30000, Ouargla, Algeria
autor
  • Earth & Univers Sciences Departement, Ziane Achour University of Djelfa. Djelfa 17000, PO Box 3117, Algeria
Bibliografia
  • 1. Azlaoui M., Nezli I.E., Foufou A., Haied N. 2017. Hydrodynamic Modeling of the Albian Aquifer of the Plain of Ain Oussera (Semi-Arid Area, Algeria). Energy Procedia, 119, 242–255.
  • 2. Adimalla N., Taloor A.K. 2020. Hydrogeochemical investigation of groundwater quality in the hard rock terrain of South India using Geographic Information System (GIS) and groundwater quality index (GWQI) techniques. Groundwater for Sustainable Development, 10, 100288.
  • 3. Agung-Setianto A.S., Tamia-Triandini T.T. 2013. Comparison of kriging and inverse distance weighted (IDW) interpolation methods in lineament extraction and analysis. Journal of Southeast Asian Applied Geology, 5(1), 21–29.
  • 4. Ayad A. (1983). Etude hydrogéologique de la nappe d’Ain Oussera.
  • 5. Babiker I.S., Mohamed M.A., Hiyama T. 2007. Assessing groundwater quality using GIS. Water Resources Management, 21(4), 699–715.
  • 6. Balan I.N., Shivakumar M., Kumar P.D. 2012. An assessment of groundwater quality using water quality index in Chennai, Tamil Nadu, India. Chronicles of young scientists, 3(2).
  • 7. Brown R.M., McClelland N.I., Deininger R.A., O’Connor M.F. 1972. A water quality index-crashing the psychological barrier. In Indicators of environmental quality (pp. 173–182). Springer, Boston, MA.
  • 8. Bouslah S., Lakhdar D., Larbi H. 2017. Water quality index assessment of Koudiat Medouar Reservoir, northeast Algeria using weighted arithmetic index method. Journal of water and land development.
  • 9. Bouderbala A. 2017. Assessment of water quality index for the groundwater in the upper Cheliff plain, Algeria. Journal of the Geological Society of India, 90(3), 347–356.
  • 10. Ben Alaya M., Zemni T., Mamou A., Zargouni F. 2014. Acquisition de salinité et qualité des eaux d’une nappe profonde en Tunisie: approche statistique et géochimique. Hydrological Sciences Journal, 59(2), 395–419.
  • 11. Caratini C. 1970. Etude geologique de la region de Chellala-Reibell: Publ. Serv. Geol. Algerie (NS), Bull, 40, 238.
  • 12. Chauhan A., Singh S. 2010. Evaluation of Ganga water for drinking purpose by water quality index at Rishikesh, Uttarakhand, India. Report and opinion, 2(9), 53–61.
  • 13. Chowdhury R.M., Muntasir S.Y., Hossain M.M. 2012. Water quality index of water bodies along Faridpur-Barisal road in Bangladesh. Glob Eng Tech Rev, 2(3), 1–8.
  • 14. DPAT. 2020. Monographie de la Wilaya de Djelfa. Direction de la Planification et de l’Aménagement du Territoire.
  • 15. Gorai A.K., Kumar S. 2013. Spatial distribution analysis of groundwater quality index using GIS: a case study of Ranchi Municipal Corporation (RMC) area. Geoinfor Geostat: An Overview, 1(2), 1–11.
  • 16. Guettaf M., Maoui A., Ihdene Z. 2017. Assessment of water quality: a case study of the Seybouse River (North East of Algeria). Applied water science, 7(1), 295–307.
  • 17. Hamlat A., Guidoum A. 2018. Assessment of groundwater quality in a semiarid region of Northwestern Algeria using water quality index (WQI). Applied Water Science, 8(8), 1–13.
  • 18. Hajji S., Younes I., Affes S., Boufi S., Nasri M. 2018. Optimization of the formulation of chitosan edible coatings supplemented with carotenoproteins and their use for extending strawberries postharvest life. Food Hydrocolloids, 83, 375–392.
  • 19. Ibrahim M.N. 2019. Assessing groundwater quality for drinking purpose in Jordan: application of water quality index. Journal of Ecological Engineering, 20(3).
  • 20. JORADP. 2011. Executive Decree No. 11–125 of March 23, 2011 on the quality of water for human consumption in Algeria. Official J of People’s Democratic Republic of Algeria. 18, 6–9. https ://www. jorad p.dz/FTP/jo-franc ais/2011/F2011 018.pdf.
  • 21. Kawo N.S., Karuppannan S. 2018. Groundwater quality assessment using water quality index and GIS technique in Modjo River Basin, central Ethiopia. Journal of African Earth Sciences, 147, 300–311.
  • 22. Khan M.Y.A., ElKashouty M., Bob M. 2020. Impact of rapid urbanization and tourism on the groundwater quality in Al Madinah city, Saudi Arabia: a monitoring and modeling approach. Arabian Journal of Geosciences, 13(18), 1–22.
  • 23. Kelley W.P. (1951). Alkali soils. LWW, 72(5), 403.
  • 24. Mays L. W., Todd D.K. 2005. Groundwater Hydrology. John Wily and Sons, Inc., Arizona State University, Third addition.
  • 25. Mebrouk N., Blavoux B., Issadi A., Marc V. 2007. Geochemical and isotopic characterization of highmg ground waters in Endorheic basin, Ain oussera Algeria. J Environ Hydrol, 15, 26.
  • 26. Misra A.K. 2014. Climate change and challenges of water and food security. International Journal of Sustainable Built Environment, 3(1), 153–165.
  • 27. Qadir M., Sharma B.R., Bruggeman A., Choukr-Allah R., Karajeh F. 2007. Non-conventional water resources and opportunities for water augmentation to achieve food security in water scarce countries. Agricultural water management, 87(1), 2–22.
  • 28. Ragab R., Prudhomme C. 2002. Sw—soil and Water: climate change and water resources management in arid and semi-arid regions: prospective and challenges for the 21st century. Biosystems engineering, 81(1), 3–34.
  • 29. Rao N.S. 2018. Groundwater quality from a part of Prakasam district, Andhra Pradesh, India. Applied water science, 8(1), 1–18.
  • 30. Rachedi L.H., Amarchi H. 2015. Assessment of the water quality of the Seybouse River (north-east Algeria) using the CCME WQI model. Water Science and Technology: Water Supply, 15(4), 793–801.
  • 31. Ravikumar P., Venkatesharaju K., Somashekar R.K. 2010. Major ion chemistry and hydrochemical studies of groundwater of Bangalore South Taluk, India. Environmental monitoring and assessment, 163(1), 643–653.
  • 32. Sadashivaiah C.R.R.C., Ramakrishnaiah C.R., Ranganna G. 2008. Hydrochemical analysis and evaluation of groundwater quality in Tumkur Taluk, Karnataka State, India. International journal of environmental research and public health, 5(3), 158–164.
  • 33. Singh P., Thakur J.K., Singh U.C. 2013. Morphometric analysis of Morar River Basin, Madhya Pradesh, India, using remote sensing and GIS techniques. Environmental Earth Sciences, 68(7), 1967–1977.
  • 34. Schwartz P.D.F. 1990. Physical and Chemical Hydrogeology Wiley New York.
  • 35. Srinivasamoorthy K., Gopinath M., Chidambaram S., Vasanthavigar M., & Sarma V.S. 2014. Hydrochemical characterization and quality appraisal of groundwater from Pungar sub basin, Tamilnadu, India. Journal of King Saud University-Science, 26(1), 37–52.
  • 36. Tyagi S., Sharma B., Singh P., Dobhal R. 2013. Water quality assessment in terms of water quality index. american Journal of water resources, 1(3), 34–38.
  • 37. Tiwari A.K., Singh A.K., Mahato M.K. 2018. Assessment of groundwater quality of Pratapgarh district in India for suitability of drinking purpose using water quality index (WQI) and GIS technique. Sustainable Water Resources Management, 4(3), 601–616.
  • 38. USSL. 1954. US Salinity Lanboratory Staff, Diagnosis and improvement of saline and alkali soils. Agric Handbook 60:83–100
  • 39. Vasanthavigar M., Srinivasamoorthy K., Vijayaragavan K., Ganthi R.R., Chidambaram S., Anandhan P., Vasudevan S. 2010. Application of water quality index for groundwater quality assessment: Thirumanimuttar sub-basin, Tamilnadu, India. Environmental monitoring and assessment, 171(1), 595–609.
  • 40. Wang Y.J., Qin D.H. 2017. Influence of climate change and human activity on water resources in arid region of Northwest China: An overview. Advances in Climate Change Research, 8(4), 268–278.
  • 41. Williams W.D. 1999. Salinisation: A major threat to water resources in the arid and semi-arid regions of the world. Lakes & Reservoirs: Research & Management, 4(3–4), 85–91.
  • 42. WHO. 2011. Guidelines for drinking-water quality world health organization, 4th edn, Geneva, Switzerland.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d7dafc7b-d4ca-4640-8547-30374f956953
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