Assessment of the vulnerability and sensitivity of groundwater for drinking water supply and irrigation: The case of the Mitidja alluvial aquifer (Northern Algeria)
1
University of Blida 1, RLPPWR, Algeria
2
National High School of Hydraulics (NHSH), Algeria
3
GEOexplorer Impresa Sociale S.r.l., Italy
4
Higher Normal School (HNS), AEBL, Algeria
Submission date: 2024-10-30
Final revision date: 2025-01-21
Acceptance date: 2025-01-23
Publication date: 2025-04-14
Geomatics, Landmanagement and Landscape 2025;(1)
KEYWORDS
TOPICS
ABSTRACT
The aim of this study is to combine the hydrochemical data, geostatistical methods, and numerical approaches with the water pollution vulnerability index of the Mitidja alluvium. This index is obtained by applying the DRASTIC model and a numerical rating system to develop a methodology based on the water sensitivity index. The socio-economic development has led to the overexploitation of groundwater and surface water resources, coupled with insufficient rainfall, which has exacerbated the sensitivity and vulnerability of this precious resource. Compared to previous studies, the most recent sensitivity map serves as an important decision support tool for relevant authorities. According to the survey, this index was very low, accounting for 45.43% of the total drinking water area in 2010. It decreased to 8.25% and later increased to 28.06% in 2018. The high and very high sensitivity index to water pollution (SI) accounted for 5.34% and 9.87% in 2010, and 19.77% and 15.78% in 2018. The variation in irrigation water sensitivity was similar that of drinking water sources (DWS). The medium and high sensitivity indices (SI) increased from 27.21% and 18.20% to 37.19% and 42.01%, reflecting a significant and alarming increase in groundwater sensitivity, vulnerability, and pollution within the study area. The results of the geostatistical approach yielded some interesting results, considering the water intended for drinking water supply and the water intended for irrigation separately in the Mitidja alluvial aquifer.
REFERENCES (37)
1.
Aller I., Benett T. 1987. DRASTIC a standardized system for evaluation of ground water pollution. Potential using hydrogeology setting. Rapport EPA, NWWA. Ohio, USA, 455, 22 carts.
2.
Ayme A. 1956. Contribution à l’étude de la plaine de la Mitidja occidentale et de sa bordure.
3.
Aziez O. 2021. Efficacité économique et environnementale des instruments de gestion de l’eau, pour des eaux souterraines utilisées en irrigation dans la Mitidja ouest. Thèse de doctorat Es-science. Université Aboubakr Belkaïd. Tlemcen. Faculté de Technologie, 220 p.
4.
Bennie et Partners. 1983. Schéma d’aménagement des ressources en eau dans la région d’Alger.
5.
Benouara N., Bouchehed H., Retima N. et al. 2024. Evaluation of Groundwater Quality for Irrigation Purposes Using Water Quality Indices and GIS Technique: A Case Study of Seriana Plain Northeastern Algeria. Dokl. Earth Sc., 515, 477–489. https://doi.org/10.1134/S10283....
6.
Benziada M. 1994. Etude hydrogéologique de la plaine de la Mitidja Est. Application d’un modèle mathématique ‘ASM’ au bassin côtier algérois. Thèse de Doctorat. Université de Franche-Comté en Sciences de la Terre.
7.
Bouderbala A. 2019. The impact of climate change on groundwater resources in coastal aquifers: Case of the alluvial aquifer of Mitidja in Algeria. Environmental Earth Sciences, 78, 698. https://doi.org/10.1007/s12665....
8.
Copernicus. 2023. Surface air temperature for July 2023. Implemented by ECMWF as part of The Copernicus Programme. https://climate.copernicus.eu/....
9.
Djabri L., Hani A., Mania J., Mudry J. 2003. L’Algérie, un pays en développement. A-t-elle déjà développé un biseau salé? Technologia de l’intrusion de agua de mar en acuiferos costeros. Madrid.
10.
Djoudar Hallal D. 1993. Approche du comportement hydrodynamique d’un système aquifère alluvial. Zone Oued El Harrach/Oued El Hamiz (Mitidja/Algérie). Mémoire d’ingénieur. IST/USTHB Alger.
11.
Djoudar Hallal D., Toubal A.C. 2012a. Contribution à l’étude de la pollution des eaux souterraines : Cas de la nappe du Haut Chellif . Bulletin du Service Géologique National de l’Algérie (SGA). ANGCM. Vol. 23. N°1.pp 71-83. 2012.
12.
Djoudar Hallal D., Toubal A.C. 2012b. Indexation de la sensibilité combinée à l’évaluation du risque de dégradation de la qualité des eaux souterraines à la pollution. Cas de la nappe alluviale de la Mitidja. IAHS – Medfriend Conference, 14–16 November, Istanbul.
13.
Djoudar Hallal D., Toubal A.C. 2014. Geostatistical modeling of nitrate pollution of groundwater in the Mitidja. 6th IAHS International Symposium on Integrated Water Resources Management 4-6 June Bologna. Italie.
14.
Djoudar D. 2014. Methodological approach of the vulnerability of the underground water resource in a strongly urban area: example in Algeria of the coastal plains (Mitidja). Doctorate Es-Sciences thesis, FSTGAT, USTHB, Alger.
15.
Djoudar D. et al. 2019. Application of the GALDIT method combined with geostatistics at the Bouteldja aquifer (Algeria). Environ. Earth Sci., 78, 22.
16.
Drouiche A. 2012. Contribution à l’étude de la vulnérabilité spécifique à la pollution par les éléments en traces métalliques et les hydrocarbures. Cas de la nappe d’eau souterraine de la Mitidja-Est. Université des sciences et de la technologie Houari Boumediène (USTHB). Magistère.
17.
Durand Delga M. 1969. Mise au point sur la structure du NE de la Berbérie. Publ. Serv. Carte géologique. Algérie, 39, 85–131.
19.
Glangeaud A. 1952. Etude géologique de la région littorale d’Alger. Bull. Serv. Carte. Géol. Algérie, 2 , 8.
20.
Gouaidia et al. 2012. Évaluation de la salinité des eaux souterraines utilisées en irrigation et risques de dégradation des sols: exemple de la plaine de Meskiana (Nord-Est Algérien) Physio-Géo, 6, 1, 141–160.
21.
Guastaldi E., Del Frate A. 2012. Risk analysis for remediation of contaminated sites: The geostatistical approach. Environmental Earth Sciences, 65(3), 897–916. http://dx.doi.org/10.1007/s126....
22.
Guastaldi E., Graziano L., Liali G. et al. 2014. Intrinsic vulnerability assessment of Saturnia thermal aquifer by means of three parametric methods: SINTACS, GODS and COP. Environ. Earth Sci., 72, 2861–2878. https://doi.org/10.1007/s12665....
23.
Guendouz A., Moula A. 2017. Assessment of seawater intrusion in the bay of Algiers (Algeria) by means of a combined isotope hydrology and hydrogeochemistry approach. October 2017 Conference: Eau – Société – Climat (ESC-2017), Hammamet, Tunisia.
24.
Hadjoudj O. 2008. Pollution des nappes aquifères de la Mitidja par les nitrates. Thèse de doctorat de l’Université d’Alger, Benyoucef Benkhedda, p. 290.
25.
Haouchine A. et al. 2016. Assessment of risk related to Coastal Aquifers Management in Algeria. La Houille Blanche, 102, 6, 36–43. https://doi.org/10.1051/lhb/20....
26.
Ikhlef N., Tachi S.E., Bouguerra H. et al. 2024. Classification of Groundwater Quality for Irrigation Purposes in Wetland Region by Irrigation Water Quality Index. Water Resources, 51, 322–331. https://doi.org/10.1134/S00978....
27.
Khous D., Aitamar H., Belaid M., Chorfi H. 2019. Geochemical and isotopic assessment of groundwater quality in the alluvial aquifer of the Eastern Mitidja Plain. Water Resources, 46(3), 443–453. https://doi.org/10.1134/S00978....
28.
Mania J., Imersoukene S., Braillon J.M. 1985. Pollution saline de la nappe côtière à l’est d’Alger. Revue Hydrogéologie, 3, 213–226.
29.
Margat J. 1968. Vulnerabilite des nappes d’eau souterraine a la pollution (Groundwater Vulnerability to Contamination). Bases de la cartographie (Doc.) 68 SGC 198HYD, BRGM, Orleans.
30.
Medjdoub Leulmi S., Aidaoui A., Djoudar Hallal D., Khelfi M.A., Lobo Ferraira J.P., Ammari A., Aziez O. 2021. Spatio-temporal analysis of nitrates and piezometric levels in groundwater using geostatistical approach: Case study of the Eastern Mitidja Plain, North of Algeria. 27 February. Arabian Journal of Geosciences, 14, 386. doi.org/10.1007/s12517-021-06642-1.
31.
NWRA. 2018. National Water Resources Agency. General Directorate of Algiers, Algeria.
32.
Ouchene B., Moroncini O. 2018. De l’économie socialiste à l’économie de marché: l’Algérie face à ses problèmes écologiques. https://doi.org/10.4000/vertig....
33.
PAC. 2004. Maitrise de l’urbanisation et de l’artificialisation des sols. Projet d’aménagement. Rapport: Etude prospective de l’urbanisation Phase 2. 66 pages.
34.
Pusatli T.O., Camur Z.M., Yazicigil H. 2007. Susceptibility indexing method for irrigation water management planning: Applications to K. Menderes river basin. Turkey. Department of Geological Engineering. Middle East Technical University. Ankara. Turkey. Journal of Environmental Management, 90, 1, 341–347.
35.
Saidi S., Bouri S., Bendhia H., Anselem B. 2009. A GIS based susceptibility indexing method for irrigation and drinking water management planning: Application to Chebba – Melloulich aquifer. Tunisia.
36.
Tachi S.E., Bouguerra H., Djellal M. et al. 2023. Assessing the Risk of Groundwater Pollution in Northern Algeria through the Evaluation of Influencing Parameters and Ensemble Methods. Dokl. Earth Sci., 513, 1233–1243. https://doi.org/10.1134/S10283....
37.
WHO. 2011. World Health Organization. Guidelines for drinking-water quality, 4th ed.
| ISSN: | 2300-1496 |
We process personal data collected when visiting the website. The function of obtaining information about users and their behavior is carried out by voluntarily entered information in forms and saving cookies in end devices. Data, including cookies, are used to provide services, improve the user experience and to analyze the traffic in accordance with the Privacy policy. Data are also collected and processed by Google Analytics tool (more).
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
