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Multivariate Statistical Analysis of Groundwater Quality of Hassi R'mel, Algeria

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The quality of Groundwater is characterized by physico-chemical parameters. They determine the way in which this water is used (water supply, irrigation, industry, etc.). This present study gives the highlighting of the hydrogeological and physico-chemical characteristics of aquifer waters in question resulting from the various wells, which aims to; gather, exploit and analyze the data, in order to determine their conformity with potability standards and their suitability for irrigation. Using multivariate statistical techniques including Principal Component Analysis (PCA), Hierarchical Cluster Analysis (ACH) and Diagram Analysis. They are applied to a dataset composed of 17 boreholes with 12 chemical variables over the entire study area, they were sampled in 2020. These boreholes are the principal water resources suppling Hassi R'mel w. Laghouat region in terms of drinking water and irrigation. Obtained results showed that the majority of groundwater in the Hassi R’mel region is hard; where approximately 20% of boreholes are characterized by fairly soft water, and approximately 5% are characterized by very hard water.
Rocznik
Strony
22--31
Opis fizyczny
Bibliogr. 34 poz., rys., tab.
Twórcy
  • Department of Civil Engineering, Faculty of Science and Applied Science, University of Akli Mohand Oulhadj, Bouira, 10000, Algeria
  • Water Engineering Department, Institute of Technology, University of Akli Mohand Oulhadj, Bouira, 10000, Algeria
  • Industrial Chemical Technology Department, Institute of Technology, University of Akli Mohand Oulhadj, Bouira, 10000, Algeria
  • Department of Civil Engineering, Faculty of Science and Applied Science, University of Akli Mohand Oulhadj, Bouira, 10000, Algeria
Bibliografia
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  • 2. Anazawa K., Ohmori H. 2005. The hydrochemistry of surface waters in andesitic volcanic area, Norikura volcano, central Japan. Chemosphere, 59(5), 605–615.
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  • 4. Aït Ouali R., Nedjari A. 1996. La province triasique saharienne. 20 ans d’informations géologiques: bilan critique et réflexions. Bulletin du Service Géologique de l’Algérie, 7(2), 211–228.
  • 5. Baouche R., Baddari K., Djeddi M. 2012. Analyse faciologiques des formations triasiques des puits de Hassi R’Mel à partir des diagraphies différées : reconnaissances des paléosols. Africa Géosciences Review, 3, 191–213.
  • 6. Barkat A., Bouaicha F., Bouteraa O., Mester T., Ata B., Balla D., Rahal Z., Szabó G. 2021. Assessment of Complex Terminal Groundwater Aquifer for Different Use of Oued Souf Valley (Algeria) Using Multivariate Statistical Methods, Geostatistical Modeling, and Water Quality Index, Water, 13, 1609.
  • 7. Belkhiri L., Boudoukha A., Mouni L., Baouz T. 2010. Application of multivariate statistical methods and inverse geochemical modeling for characterization of groundwater case study: Ain Azel plain (Algeria). Geoderma, 159, 390–398.
  • 8. Bencer S., Boudoukha A., Mouni L. 2016. Multivariate statistical analysis of the groundwater of Ain Djacer area (Eastern of Algeria). Arabian Journal of Geosciences, 9, 248.
  • 9. Bengherbia A., Hamaidi F., Zahraoui R., Hamaidi M.S., Megateli S. 2014. Impact des rejets des eaux usées sur la qualité physico-chimique et bactériologique de l’Oued Beni Aza (Blida, Algérie). Lebanese science journal, 15(2), 39–51.
  • 10. Blake S., Henry T., Murray J., Flood R., Muller M.R., Jones A.G., Rath V. 2016. Compositional multivariate statistical analysis of thermal groundwater provenance: A hydrogeochemical case study from Ireland, Applied Geochemistry, 75, 171–188.
  • 11. Chen K., Liu Q., Yang T., Ju Q., Feng Y. 2022. Statistical analyses of hydrochemistry in multi-aquifers of the Pansan coalmine, Huainan coalfield, China: implications for water-rock interaction and hydraulic connection. Heliyon, 8(9), e10690.
  • 12. Christofi C., Bruggeman A., Kuells C., Constantinou C. 2020. Hydrochemical evolution of groundwater in gabbro of the Troodos Fractured Aquifer. A comprehensive approach. Applied Geochemistry, 114, 104–524.
  • 13. Dagnélie P. 2006. Theoretical and applied statistics. Tome 2: inferences and a two-dimensional. Edis. Boeck & Larcier, Bruxelles-Univ.
  • 14. Djafer Khodja H., Aichour A., Rezig A., Baloul D., Ferhati A. 2022. Application of Multivariate Statistical Methods to the Hydrochemical Study of Groundwater Quality in the Sahel Watershed, Algeria, Journal of Ecological Engineering, 23(8), 341–349.
  • 15. Duffy C., Brandes D. 2001. Dimension reduction and source identification formultispecies groundwater contamination. Journal of Contaminant Hydrology, 48(1–2), 151–165.
  • 16. Ferhati A., Belazreg N. H., Dougha M al. 2022. Spatio-temporal assessment of groundwater quality: a case study of M’sila province (Algeria). Arabian Journal of Geosciences, 15, 1775.
  • 17. Ferhati A., Mitiche-Kettab R., Belazreg N.E.H., Djafer Khodja H., Djerbouai S., Hasbaia M. 2023. Hydrochemical analysis of groundwater quality in central Hodna Basin, Algeria: a case study. International Journal of Hydrology Science and Technology, 15(1), 22–39.
  • 18. Hamel A., Mania J. et Perriaux J. 1988. Etude géologique des grès triasiques du gisement pétrolier de Hassi R’Mel (Algérie). Caractérisation, extension et milieu de dépôt, Ph.D. Thesis, University of Franche-Comté, France.
  • 19. Khechana S., Derradji E.F. 2014. Qualité des eaux destinées à la consommation humaine et à l’utilisation agricole (Cas des eaux souterraines d’Oued-Souf, SE algérien). Synthèse: Revue des Sciences et de la Technologie, 28, 58–68.
  • 20. Khedidja A., Boudoukha A. 2014. Risk assessment of agricultural pollution on groundwater quality in the high valley of Tadjenanet-Chelghoum Laid (Eastern Algeria). Desalination Water Treatment 52(22–24), 4174–4182.
  • 21. Khelif S., Boudoukha A. 2018. Multivariate statistical characterization of groundwater quality in Fesdis, East of Algeria, journal of water and land development, 2018, 37(IV–VI), 65–74.
  • 22. Official Journal of the Algerian Republic, 2011. Executive Decree No. 11-125 of 17 Rabie Ethani 1432, corresponding to March 22, 2011 relating to the quality of water for human consumption.
  • 23. Rahal O., Gouaidia L., Fidelibus M.D., Marchina C., Natali C., Bianchini G. 2021. Hydrogeological and geochemical characterization of groundwater in the F’Kirina plain (eastern Algeria). Applied Geochemistry, 130, 104983.
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  • 25. Rouabhia A., Baali F., Fehdi C., Abderrahmane B., Djamel, B. 2011. Hydrogeochemistry of groundwaters in a semi-arid region. El Ma El Abiod aquifer, Eastern Algeria. Arabian Journal of Geosciences, 4(5–6), 973–982.
  • 26. Ruiz-Pico A., Cuenca A.P., Serrano-Agila R., Criollo D.M., Leiva-Piedra J., Salazar-Campos J. 2019. Hydrochemical characterization of groundwater in the Loja Basin (Ecuador). Applied Geochemistry, 104, 1–9.
  • 27. Seikhy Narany T., Ramli M.R., Aris A.Z., Sulaiman W.N.A., Fakharian K. 2014. Spatiotemporal variation of groundwater quality using integrated multivariate statistical and geostatistical approaches in Amol-Babol Plain, Iran. Environmental Monitoring and Assessment, 186, 5797–5815.
  • 28. Semar A., Saibi H., et Medjerab A. 2013. Contribution of multivariate statistical techniques in the hydrochemical evaluation of groundwater from the Ouargla phreatic aquifer in Algeria. Arabian Journal of Geosciences, 6, 3427–343.
  • 29. Sinduja M., Sathya V., Maheswari M., Dinesh G.K., Prasad S., Kalpana P. 2023. Groundwater quality assessment for agricultural purposes at Vellore District of Southern India: A geospatial based study. Urban Climate, 47, 101368.
  • 30. Steli, S., Hilali M., Mahboub A., Rachid L., Barbot A. 2019. Groundwater quality assessment of the Jorf-Fezna palm grove (South-Eastern Morocco). Environmental and Water Sciences, public Health and Territorial Intelligence Journal, 3(4), 231–237.
  • 31. Thilagavathi R., Chidambaram S., Prasanna M.V., Thivya C., Singaraja C. 2012. A study on groundwater geochemistry and water quality in layered aquifers systemof Pondicherry region, southeast India. Applied Water Science, 2, 253–269.
  • 32. Tiri A., Lahbari N., Boudoukha A. 2014. Multivariate statistical analysis and geochemical modeling to characterize the surface water of Oued Chemora Basin, Algeria. Natural Ressources Research, 23(4), 379–391.
  • 33. World Health Organization, 2006. quality guidelines for drinking water, third edition. recommendation, world health organization, geneve, 78.
  • 34. Wu C., Wu X., Qian C., Zhu G. 2018. Hydrogeochemistry and groundwater quality assessment of high fluoride levels in the Yanchi endorheic region, northwest China. Applied Geochemistry, 98, 404–417.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f20d15c5-7bc1-4b52-a964-6c3ce48e3eb7
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