Impacts of Anthropogenic Factors on the Groundwater Ecosystem of Fezouata in South-East of Morocco

Boudellah, Abderrazzaq; El Moustaine, Radouane; Maliki, Abdelmounaim; Moutaouakil, Soumia; El Gharmali, Abdelhay; Boulanouar, Mohamed; El Hachimi, Youssef; Ghamizi, Mohamed

doi:10.12911/22998993/146678

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Tytuł artykułu

Impacts of Anthropogenic Factors on the Groundwater Ecosystem of Fezouata in South-East of Morocco

Autorzy

Boudellah Abderrazzaq , El Moustaine Radouane , Maliki Abdelmounaim , Moutaouakil Soumia , El Gharmali Abdelhay , Boulanouar Mohamed , El Hachimi Youssef , Ghamizi Mohamed

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DOI

10.12911/22998993/146678

Warianty tytułu

Języki publikacji

Abstrakty

The depletion of aquifer systems in arid and semiarid regions worldwide is causing acute water scarcity and quality degradation, and leading to extensive ecosystem damages. Groundwater is exposed to a variety of anthropogenic water pollution, such as raw wastewater disposal in the Draa Wadi and the use of septic tanks. In this respect, a study performed in some wells of Fezouata (South-east of Morocco) aimed at both discovering the main components of the aquatic subterranean fauna unknown up to now in this area, and the potential relationships between this fauna and the water quality The principal physico-chemical characteristics of water were measured between November 2019 to March 2021 for 15 wells, which were selected considering their position with respect to the pollution sources known in surface. The Fezouata groundwater is distinguished by its high salinity with an increasing gradient from upstream to downstream. The aquatic fauna in the 15 wells showed 12 stygofauna species. In the protected wells which are situated far from the pollution sources, the fauna is dominated by Cirolanidae, Hydrobiidae, Metacrangonctydae, Stenasellidae, and Thermosbaenacea. On the other hand, in the less protected well, close to the pollution sources, the fauna is made of epigean species, such as insect’s larva, mainly Culicidae and Chironomidae. The analysis of the water quality and the subterranean biodiversity shows that the latter decreases with increasing groundwater pollution. It seems that the impact of the acute pollution affected the stygocenose even by reducing drastically the biodiversity.

Słowa kluczowe

groundwater pollution stygobiont fauna Fezouata aquifer water quality Morocco

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 5

Strony

30--43

Opis fizyczny

Bibliogr. 52 poz., rys., tab.

Twórcy

autor

Boudellah Abderrazzaq

abderrazzaq17@gmail.com

Department of Biology, Cadi Ayyad University, 112Bd. Abdelkrim Al Khattabi Avenue, 549, 40000, Marrakech, Morocco

https://orcid.org/0000-0003-0994-5994

autor

El Moustaine Radouane

Department of Biology, Faculty of Science, University Moulay Ismail, BP 11201, Zitoune Avenue, Meknes, Morocco

autor

Maliki Abdelmounaim

Department of Biology, Faculty of Science, University Moulay Ismail, BP 11201, Zitoune Avenue, Meknes, Morocco

autor

Moutaouakil Soumia

Museum of Natural History, Cadi Ayyad University, Abdelkrim Al Khattabi Avenue, 40000 Marrakech, Morocco
Department of Biology, Faculty of Sciences Semlalia, Cadi Ayyad University, (URA 33), B.P. 2390, Boulevard de Safi, 40000, Marrakech, Morocco

autor

El Gharmali Abdelhay

Department of Biology, Faculty of Sciences Semlalia, Cadi Ayyad University, (URA 33), B.P. 2390, Boulevard de Safi, 40000, Marrakech, Morocco

autor

Boulanouar Mohamed

Department of Biology, Ecole Normale Supérieure Marrakech, B.P. 2400, Marrakech 40000, Marocco

autor

El Hachimi Youssef

Department of Biology, Cadi Ayyad University, 112Bd. Abdelkrim Al Khattabi Avenue, 549, 40000, Marrakech, Morocco

autor

Ghamizi Mohamed

Museum of Natural History, Cadi Ayyad University, Abdelkrim Al Khattabi Avenue, 40000 Marrakech, Morocco
Department of Biology, Faculty of Sciences Semlalia, Cadi Ayyad University, (URA 33), B.P. 2390, Boulevard de Safi, 40000, Marrakech, Morocco

Bibliografia

1. AitLamqadem A., Saber H., Pradhan B. 2018. Quantitative assessment of desertification in an arid Oasis using remote sensing data and spectral index techniques. Remote Sens., 10(12), 1862.
2. Angelier E. 1953. Le peuplement des sables submergés d’eau douce. Ann. Biol., 29, 467–486.
3. Berrady I.K., Essafi J., Mathieu. 2000. Comparative physico-chemical and faunal studies of two thermal spring brooks near Sidi Harazem (Morocco). Annales de Limnologie International Journal of Limnology, 36, 261–274.
4. Boujghad A., Bouabdli A., Baghdad B. 2019. Groundwater quality evaluation in the vicinity of the Draa Sfar Mine in Marrakesh, Morocco. EuroMediterr J Environ Integr, 4, 12.
5. Boulton A.J., Fenwick G., Hancock P.J., Harvey M.S. 2008. Biodiversity, functional roles and ecosystem services of groundwater invertebrates. InvertebrateSystematics, 22(2), 103–116.
6. Boutin C., Boulanouar M., Yacoubi-khebiza M. 1996. Un test biologique simple pour apprécier la toxicité de l’eau et des sédiments d’un puits. Toxicité comparée, in vitro, de quelques métaux lourds et de l’ammonium, vis à vis de trois genres de crustacés de la zoocénose des puits. Hydroécologie appliquée, 7(1–2), 91–109.
7. Boutin C., et Boulanouar M. 1983. Méthodes de capture de la faune stygobie: expérimentation de différents types de pièges appâtés dans les puits de Marrakech (Maroc occidental). Bull. Fac. Sci. Marrakech, Section Sci. de la Vie, 2, 5–21.
8. Boutin C., Idbennacer B. 2005. Faune stygobie du Sud de l’Anti-Atlas marocain premiers résultats. rseau, 2, 891–904.
9. Castaño-Sánchez A., Hose G.C., Reboleira A.S.P. 2020. Salinity and temperature increase impact groundwater crustaceans. Scientific reports, 10(1), 1–9.
10. Chappuis PA. 1953. Un nouvel Isopode psammique du Maroc: Microcerberus remyi. Vie Milieu 4(4), 659–663.
11. Cvetkov l. 1968. A biological phréato fillet. Bull. Inst. Zool. Mus. Sofia. XXVII: 215–219.
12. de Bovee F., Yacoubi-Khebiza M., Coineau N., Boutin C. 1995. Influence du substrat sur la répartition des Crustacés stygobies interstitiels du Haut-Atlas occidental. Int. Revue ges. Hydrobiol. Hydrogr., 80, 453–468.
13. Deharveng L., Stock F., Gibert J., Bedos A., Galassi D., Zagmaister M., Brancelj A., Camacho A., Fiers F., Martin P., Giani N., Magniez G. Et Marmonier P. 2009. Groundwater biodiversity in Europe. Freshwater Biology, 4(54), 709–726.
14. El Adnani M., Ait Boughrous A., Khebiza M.Y., El Gharmali A., Sbai M.L., Errouane A.S., Nejmeddine A. 2007. Impact of mining wastes on the physicochemical and biological characteristics of groundwater in a mining area in Marrakech (Morocco). Environmentaltechnology, 28(1), 71–82.
15. El Moustaine R. 2014. Effects of anthropogenic factors on groundwater ecosystem in Meknes area (Morocco). Journal of Materials and Environmental Science, 5(S1), 2086–2091.
16. El Moustaine R., Chahlaoui A., Rour E.H. 2014. Relationships between the physico-chemical variables and groundwater biodiversity: a case study from meknès area, Morocco.
17. Ferreira D., Malard F., Dole-Olivier M.J., Gibert J. 2007. Obligate groundwater fauna of France: diversity patterns and conservation implications. BiodiversConserv, 16, 567–596.
18. Ghamizi M., Bodon M., Boulal M., Giusti F. 1999. AtebbaniaBernasconii, a New Genus and Species from Subterranean Waters of the Tiznit Plain, Southern Morocco (Gastropoda: Hydrobiidae). Journal of Molluscan Studies, 65(1), 89–98.
19. Ghamizi M., Boulal M. 2017. New stygobiont snail from groundwater of Morocco (Gastropoda: Moitessieriidae). EcologicaMontenegrina, 10, 11–13. https://doi.org/10.37828/em.2017.10.2
20. Gibert J., Danielopol DL., Stanford J.A. (eds). 1994. Groundwater ecology. Academic Press, San Diego.
21. Ginet R., Decou V. 1977. Initiation à la biologie et à l’écologie souterraines Paris: J.-P. Delarge, 345.
22. Grady C.P.L., Daigger G.T., Love N.G., Filipe C.D.M. 2011. Biological wastewater treatment. 3rd ed. London. IWA Publishing, 1022.
23. Hallam F., Yacoubi-Khebiza M., Oufdou K., Boulanouar M. 2008. Groundwater quality in an arid area of Moroco: Impact of pollution on biodiversity and relationships between crustaceans and bacteria of health interest Environmental Technology, 29(11), 1179–1189.
24. Halse S., Scanlon M., Cocking J., Barron H., Richardson J., Eberhard S. 2014. Pilbara stygofauna: deep groundwater of an arid landscape contains globally significant radiation of biodiversity. Records of the Western Australian Museum, Supplement, 78, 443–483.
25. Helena B., Pardo R., Vega M., Barrado E., Fernandez M.J., Fernandez L. 2000. Temporal evolution of groundwater composition in an alluvial aquifer (Pisuerga River, Spain) by principal component analysis. Water Research, 34(3), 807–816.
26. Hölting B., Coldewey Wilhelm G. 2019. Hydrogeology; Springer International Publishing: Berlin/ Heidelberg, Germany.
27. Hose G.C., Sreekanth J., Barron O., Pollino C. 2015. Stygofauna in Australian Groundwater Systems: Extent of Knowledge; Client Report; CSIRO: Canberra, Australia, 62.
28. Humphreys W.F. 2006. Aquifers: The ultimate groundwater-dependent ecosystems, Australian Journal of Botany, 54(2), 115–132.
29. Humphreys W.F. 2008. Rising from Down Under: developments in subterranean biodiversity in Australia from a groundwater fauna perspective. InvertebrateSystematics, 22, 85–101.
30. Johns T., Jones J.I., Knight L., Maurice L., Wood P., Robertson A. 2015. Regional-scale drivers of groundwater faunal distributions. Freshw. Sci, 34, 316–328.
31. Kamarudzaman A.N., Feng V.K., Aziz R.A., Ab Jalil M.F. 2011. Study of Point and Non Point Sources Pollution A Case Study of TimahTasoh Lake in Perlis, Malaysia. International Conference on Environmental and Computer Science IPCBEE, IACSIT Press, Singapore 2011, 19.
32. Karaman G., Pesce G.P. 1980. Researches in Africa by the Zoological Institute of l’Aquila, Italy. V. On three subterranean Amphipods from North Africa (Amphipoda, Gammaridea). Bulltin de Zoologie. Museum, Univers Van Amsterdam, 7(20), 197–207.
33. Karmaoui A., Ifaadassan., Babqiqi A., Messouli M., Khebiza Y. 2016. Analysis of the water supplydemand relationship in the Middle Draa Valley, Morocco, under climate change and socio-economic scenarios. J. Sci. Res. Rep. 9(4), 1–10.
34. Khammar H., Ramzi H., Djemoi M. 2019. Biodiversity and distribution of groundwater fauna in the Oum-El-Bouaghi region (Northeast of Algeria). Biodiversitas Journal of Biological Diversity, 20(12).
35. Klose S., Reichert B., Lahmouri A. 2008. Management Options for a Sustainable Groundwater Use in the Middle Drâa Oases under the Pressure of Climatic Changes. Clim. Chang. Water Resour. Middle East N. Afr., 179–195.
36. Korbel K.L., Lim R.P., Hose G.C. 2013. An intercatchment comparison of groundwater biota in the cotton-growing region of north-western New South Wales. Crop Pasture Sci, 64, 1195–1208.
37. Mathieu J., Essafi K., Chergui H. 1999. Spatial and temporal variations of stygobite Amphipod populations in interstitial aquatic habitats of karst /floodplain interfaces in France and Morocco. Annales de Limnologie. International Journal of Limnology, 35, 133–139.
38. Merzoug D., Khiari A., Aït boughrous A., Boutin C. 2010. Faune aquatique et qualité de l’eau dans les puits et sources de la région d’Oum-el-Bouaghi Nordest algérien. Hydroécologie Appliquée, 17, 1–22.
39. Notenboom J., Plenet S., Turquin M.J. 1994. Groundwater Contamination and its Impacts on Groundwater Animals and Ecosystems. J. Gibert D.L., 477–504.
40. Notenboom J. 1991. Marine regressions and the evolution of groundwater dwelling Amphipods (Crustacea). Journal of Biogeography, 18, 437–454.
41. OMS. 2004. Genève, Santé1, 1.
42. Pesce GL., Tete P., De Simone P. 1981. Ricerchefaunistische in acque sotterranneefreatischedel Maghreb (Tunisia, Algeria, Morocco) et d’ellEgitto. Natura. Soc. Ital. Sci. nat. Museo civ Stor. nat. e acquario civ. Milano, 72(1–2), 63–98.
43. Podmore C. 2009. Irrigation salinity causes and impacts. PRIMEFACT for profitable, adaptive and sustainable primary industries, 937.
44. Reeves J.M., De Deckker P., Halse S.A. 2007. Groundwater Ostracods from the arid Pilbara region of northwestern Australia: distribution and water chemistry. Hydrobiologia, 585, 99–118.
45. Rodier J., Legube B., Merlet N., et coll. 2009. L’analyse de l’eau. Eaux naturelles, eaux résiduaires, eau de mer. Dunod, 9e, 1579.
46. Shrestha S., Kazama F. 2007. Assessment of surface water quality using multivariate statistical techniques: A case study of the Fuji river basin, Japan Environmental Modelling & Software, 22, 464–475.
47. Skrzypiec K., Gajewska M.H. 2017. The use of constructed wetlands for the treatment of industrial wastewater. Journal of Water and Land Development, 34, 233–240.
48. Togouet S.H., Boutin C., Njiné T., Kemka N., Nola M., Menbohan S.F. 2009. First data on the groundwater quality and aquatic fauna of some wells and springs from Yaounde (Cameroon). European Journal of Water Quality, 40, 51–74.
49. Tomlinson M., Boulton A. 2008. Subsurface Groundwater Dependent Ecosystems: a review of their biodiversity.
50. Ecological processes and ecosystem services, Australian Government National Water Commission Report, 77.
51. Vandel A. 1964. Biospéologie : la biologie des animaux cavernicoles. Gauthier-Villars, Paris, 620.
52. Ward J.H. 1963. Hierarchical grouping to optimise an objective function. J. Am. Stat. Ass., 58, 238244.

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