Assessment of Groundwater Pollution Vulnerability, Hazard and Risk in a Semi-Arid Region

Haied, Nadjib; Khadri, Samira; Foufou, Atif; Azlaoui, Mohamed; Chaab, Salah; Bougherira, Nabil

doi:10.12911/22998993/142234

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Tytuł artykułu

Assessment of Groundwater Pollution Vulnerability, Hazard and Risk in a Semi-Arid Region

Autorzy

Haied Nadjib , Khadri Samira , Foufou Atif , Azlaoui Mohamed , Chaab Salah , Bougherira Nabil

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DOI

10.12911/22998993/142234

Warianty tytułu

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Abstrakty

The Mio-plio-quaternary aquifer of the Djelfa Syncline is part of a region in Algeria which is characterized by the lack of surface water resources and located in a semi-arid climate. Since alluvial aquifers, and among them our aquifer, are the most vulnerable because of thier direct exposure to the pollution caused by the infiltrated pollutants, this work focused on the assessement of groundwater pollution vulnerability, hazard and risk. Thus, several methods were used; for this purpose, such as the DRASTIC and WQI methods mapped using a GIS. The results obtained clearly show a low to moderate vulnerability. The DRASTIC model and its validation based on the correlation with WQI revealed a low correlation (WQ_Ivs D_I : 0.221). Since the vulnerability model does not match with the groundwater quality, pollution risk was assessed by combining vulnerabilty and hazard (i.e, water quality). The risk map illustrated three levels ranging from low to high risk. This map should be helpful in decision making and groundwater management through avoiding high risk areas.

Słowa kluczowe

Mio-plio-quaternary aquifer Djelfa syncline DRASTIC WQI GIS pollution risk

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2021

Tom

Vol. 22, nr 10

Strony

1--13

Opis fizyczny

Bibliogr. 41 poz., rys., tab.

Twórcy

autor

Haied Nadjib

haiednajib@gmail.com

Earth and Universe Sciences Department, Ziane Achour University of Djelfa, Djelfa 17000, PO Box 3117, Algeria

https://orcid.org/0000-0002-2705-4987

autor

Khadri Samira

Biological Sciences Department, Ziane Achour University of Djelfa, Djelfa 17000, PO Box 3117, Algeria

autor

Foufou Atif

Earth and Universe Sciences Department, Ziane Achour University of Djelfa, Djelfa 17000, PO Box 3117, Algeria

autor

Azlaoui Mohamed

Department of Hydraulic, Ziane Achour University of Djelfa, Djelfa 17000, PO Box 3117, Algeria

autor

Chaab Salah

Geology Laboratory, Badji Mokhtar-Annaba University, Annaba 23000, PO Box 12, Algeria

autor

Bougherira Nabil

Water Resources and Sustainable Development Laboratory, Badji Mokhtar-Annaba University, Annaba 23000, PO Box 12, Algeria

Bibliografia

1. Abassi S.A. 1999. Water Quality Indices. State-of-the art. J.IPHE., 1.
2. Ali-Rahmani S.E., Chibane B., Boucefiène A. 2016. Groundwater recharge estimation in semi-arid zone: a study case from the region of Djelfa (Algeria). Applied Water Science, 7, 2255–2265.
3. Allechy F.B., Lasm T.H., Youan T.M., Yao K., Assemien F., Kouakou. O.S., Oka K.A.R., Baka D., De Lasme O.Z. 2016. Cartographie de la vulnerabilite à la pollution des aquiferes du socle precambrien: cas de la region d’Oume (Centre-Ouest de la Cote d’Ivoire) (in French). European Scientific Journal, 12, 20.
4. Aller L., Bennett T., Lehr J.H., Petty R.J., Hackett G. 1987. DRASTIC: a standardized system for evaluating groundwater pollution potential using hydrogeologic settings. EPA/600/2–87/035-USA: US Environmental Protection Agency.
5. Asadi S.S., Vuppala P., Anji R.M. 2007. Remote sensing and GIS techniques for evaluation of groundwater quality in Municipal Corporation of Hyderabad (Zone-V). India Int. J. Environ. Res. Publ. Health, 4(1), 45–52.
6. Azlaoui M., Zeddouri A., Haied N., Nezli I.E., Foufou A. 2021. Assessment and mapping of groundwater quality for irrigation and drinking in a semi-arid area in Algeria. Journal of Ecological Engineering, 22(8), 19–32.
7. Babiker I.S., Mohamed M.A.A., Hiyama T. 2007. Assessing groundwater quality using GIS. Water Resources Management, 21, 699–715.
8. Bharti N. & Katyal D. 2011. Water quality indices used for surface water vulnerability assessment. International Journal of Environmental Sciences, 2(1).
9. Boufekane A. & Saighi O. 2018. Application of Groundwater Vulnerability Overlay and Index Methods to the Jijel Plain Area (Algeria). Groundwater, 56(1), 143–156.
10. Brown R.M., McClelland N.I., Deininger R.A., Tozer R.G. 1970. Water quality index-do we dare? Water Sewage Works, 117(10), 339–343.
11. Chibane B., Boutaleb A., Lacroix M. 2010. Etude hydrochimique et Approche Isotopique en Région semi-aride: cas du Synclinal de Djelfa (Algérie) (in French). European Journal of Scientific Research, 45(2), 270–290.
12. Chibane B. & Ali-Rahmani S.E., 2015. Hydrological based model to estimate groundwater recharge, ealevapotranspiration and runoff in semi-arid area (in French). Larhyss Journal, 231–242.
13. Dwivedi S.L. & Pathak V. 2007. A preliminary assignment of water quality index to Mandakini river, Chitrakoot. Indain J. Environmental Protection, 27, 1036–1038.
14. Engel B.A., Navulur, K.C.S., Cooper B.S., Hahn L. 1996. Estimating groundwater vulnerability to non-point source pollution from nitrates and pesticides on a regional scale. Int. Assoc. Hydrol. Sci., 235, 521–526.
15. Foufou A., Djorfi S., Haied N., Kechiched R., Azlaoui M., Hani A. 2017. Water pollution diagnosis and risk assessment of Wadi Zied plain aquifer caused by the leachates of Annaba landfill (N-E Algeria). Energy Procedia, 119(2017), 393–406.
16. Freeze R.A. & Cherry J.A. 1979. Groundwater. Prentice-Hall, New Jersey.
17. Heiß L., Bouchaou L., Tadoumant S., Reichert B. 2020. Index-based groundwater vulnerability and water quality assessment in the arid region of Tata city (Morocco). Groundwater for Sustainable Development, 10(2020), 100344.
18. Horton R.K. 1965. An index number system for rating water quality. J. Water Pollu. Cont. Fed., 37(3), 300–305.
19. Huan H., Wang J., Teng Y. 2012. Assessment and validation of groundwater vulnerability to nitrate based on a modified DRASTIC model: A case study in Jilin City of northeast China. Science of the Total Environment, 440(2012), 14–23.
20. Jasem A.H. & Alraggad M. 2010. Assessing groundwater vulnerability in Azraq Basin area by a modified DRASTIC index. J. Water Resource and Protection, 2, 944–951.
21. Ketata M., Gueddari M., Bouhlila R. 2012. Use of geographical information system and water quality index to assess groundwater quality in El Khairat deep aquifer (Enfidha, Central East Tunisia). Arabian Journal of Geosciences, 5, 1379–1390.
22. Khan A.A., Paterson R., Khan H. 2003. Modification and application of the CCME WQI for the communication of drinking water quality data in new found land and labrador. Presented at 38th, Central Symposium on Water Quality Research, Canadian Association on Water Quality 10–11 February 2003, Burlington, Canada.
23. Knox R.C., Sabatini D.A., Canter L.W. 1993. Subsurface transport and fate processes. Lewis Publishers, USA.
24. Krishan G., Singh S., Kumar C.P., Garg P.K., Gurjar S., Ghosh N.C., Chaudhary A. 2016. Assessment of groundwater quality for drinking purpose by using water quality index (WQI) in Muzaffarnagar and Shamli districts, Uttar Pradesh, India. Hydrology Current Research, 7(1), DOI: 10.4172/2157–7587.1000227.
25. Kumar K.S., Kumar C.S., Prrasad K.H., Rajesh B., Prasad R.S., Venkatesh T. 2015. Assessment of ground water quality using water quality index. International Journal of Innovative Research in Advanced Engineering (IJIRAE), 2(3), 103–108.
26. Mardhel V., Pinson S., Gravier A. 2005. Cartographie de la vulnérabilité intrinsèque des eaux souterraines en région Nord-Pas-de-Calais (in French). (BRGM/RP – 54238 – FR Décembre 2005).
27. Mitra B.K. 1998. Spatial and temporal variation of ground water quality in sand dune area of Aomori prefecture in Japan. 062023, 2006 ASAE Annual Meeting.
28. NRC. 1993. Groundwater vulnerability assessment: Predicting relative contamination potential under conditions of uncertainty. Committee for Assessing Groundwater Vulnerability, 210. Washington, DC: National Academy Press.
29. Pradhan S.K., Patnaik D., Rout S.P. 2001. Water quality index for the ground water in and around a phosphatic fertilizer plant. Indian Journal of Environmental Protection, 21, 355–358.
30. Ramakrishnaiah C.R., Sadashivaiah C., Ranganna G. 2009. Assessment of water quality index for the groundwater in Tumkur Taluk, Karnataka State. India. E-Journal of Chemistry, 6(2), 523–530.
31. Reza R. & Singh G. 2010. Assessment of ground water quality status by using water quality index method in Orissa, India. World Appl. Sci. J., 9(12), 1392–1397.
32. Satouh A., Bouselsal B., Chellat S., Benaabidate L. 2021. Determination of groundwater vulnerability using the drastic method in Ouargla shallow aquifer (Algerian Sahara). Journal of Ecological Engineering, 22(6), 12–19.
33. Şener Ş., Şener E., Davraz A. 2017. Evaluation of water quality using water quality index (WQI) method and GIS in Aksu River (SW-Turkey). Science of the Total Environment, 584–585, 131–144.
34. Srinivasamoorthy K., Chidambaram M., Prasanna M.V., Vasanthavigar M., John Peter A., Anandhan P. 2008. Identification of major sources controlling Groundwater Chemistry from a hard rock terrain-a case study from Mettur taluk, Salem district. Tamilnadu, India. Journal of Earth System Sciences, 117(1), 49–58.
35. Taabni M. & El Jihad M.D. 2012. Eau et changement climatique au Maghreb: quelles stratégies d’adaptation? (in French). Les Cahiers d’Outre-Mer, Revue de Géographie de Bordeaux, 260, 493–518.
36. USGS (US Geological Survey). 2019. EarthExplorer. http://earthexplorer.usgs.gov. Accessed September 2019.
37. Vasanthavigar M., Srinivasamoorthy K., Rajiv Gantha R., Vijayaraghavan K., Sarma V.S. 2010. Characterization and quality assessment of groundwater with special emphasis on irrigation utility: Thirumanimuttar sub-basin, Tamil Nadu, India. Arab.Geosci. J. DOI: 10 1007/s12517–010–0190–6.
38. Vrba J. & Zaporozec A. 1994. Guidebook on mapping groundwater vulnerability. Int Contrib Hydrol, 16, 131.
39. WHO. 2011. Guidelines for drinking-water quality world health organization, 4th edn, Geneva, Switzerland.
40. Wisner B., Blaikie P., Cannon T., Davis I. 2004. At Risk, Natural hazard, people’s vulnerability and disasters. 2nd edn. Routledge Taylor & Francis Group, London and New York, 49–52.
41. Yidana S.M. & YidanaA. 2010.Assessing water quality using water quality index and multivariate analysis. Environmental Earth Sciences, 59, 1461–1473.

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Bibliografia

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