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Knowledge of the quantity and quality of groundwater is a prerequisite to encourage investment in the development of a region and to consider the sedentarisation of populations. This work synthesises and analyses data concerning the chemical quality of the available water acquired in the Foum el Gueiss catchment area in the Aures massif. Two families of waters are observed, on the one hand, calcium and magnesian chlorated-sulphate waters and on the other hand, calcium and magnesium bicarbonate waters. Multivariate statistical treatments (Principal Component Analysis – PCA and Discriminant Analysis – DA) highlight a gradient of minerality of the waters from upstream to downstream, mainly attributed to the impact of climate, and pollution of agricultural origin rather localised in the lower zones. These differences in chemical composition make it possible to differentiate spring, well and borehole waters. The main confusion is between wells and boreholes, which is understandable because they are adjacent groundwater, rather in the lower part of the catchment area. The confusion matrix on the dataset shows a complete discrimination with a 100% success rate. There is a real difference between spring water and other samples, while the difference between wells and boreholes is smaller. The confusion matrix for the cross-validation (50%).
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Tom
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60--65
Opis fizyczny
Bibliogr. 24 poz., rys., tab., wykr.
Twórcy
autor
- University 8 May 1945, Faculty of Natural and Life Sciences and Earth Sciences and Universe, Department Ecology and Environment, P.O. Box 401, Guelma, 24000, Algeria
- Abbes Laghrour University, Department of Ecology and Environment, Khenchela 40004, Algeria
autor
- University 8 May 1945, Faculty of Natural and Life Sciences and Earth Sciences and Universe, Department Ecology and Environment, P.O. Box 401, Guelma, 24000, Algeria
autor
- Avignon University, National Research Institute for Agriculture, Food and the Environment, Mediterranean Environment and Modeling of Agro-Hydrosystems, Avignon, France
autor
- The National Center for Scientific Research, Toulouse University, Midi-Pyrénées Observatory, UMR 5563, Géoscience Environement Toulouse, Toulouse, France
autor
- Abbes Laghrour University, Department of Ecology and Environment, Khenchela 40004, Algeria
autor
- Ouagadougou University Professor Joseph Ki-Zerbo, Ouagadougou, Burkina Faso
autor
- Mohammed V University, Faculty of Sciences, Geoscience, Water and Environment Laboratory, Rabat, Morocco
autor
- Abbes Laghrour University, Department of Ecology and Environment, Khenchela 40004, Algeria
Bibliografia
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- COTE M. 1974. Les régions bioclimatiques de l’est algérien (CURER) [The bioclimatic regions of eastern Algeria (CURER)]. University of Constantine pp. 15.
- GARCÍA G.M., HIDALGO M.D.V., BLESA M.A. 2001. Geochemistry of groundwater in the alluvial plain of Tucuman province, Argentina. Hydrogeology Journal. Vol. 9(6) p. 597–610.
- HOUHA B., KHERICI N., KACHI S., VALLES V. 2008. Hydrochemical differentiation of salinisation process of the water in Endoreic Semi-Arid Basin: Case of Rémila Basin, Alegria. American Journal of Applied Sciences. Vol. 5(7) p. 891–895.
- JACKSON R.B., CARPENTER S.R., DAHM C.N., MCKNIGHT D.M., NAIMAN R.J., POSTEL S.L., RUNNING S.W. 2001. Water in a changing world. Ecological Applications. Vol. 11(4) p. 1027–1045.
- JOLLIFFE I.T. 2002. Principal component analysis. 2nd ed. New York. Springer. ISBN 978-0-387-22440-4 pp. 488.
- LAFITTE R. 1939. Structure et relief de l’Aurès (Algérie) [Structure and relief of the Aures (Algeria)]. Bulletin de l’Association de Géographes Français. No. 119 p. 34–40.
- LESSARD L. 1952. La géologie et les problèmes de l’eau en Algérie. T. 1 : Eléments de Technogéologie des Barrages Algériens et de quelques ouvrages annexes – Le barrage de Foum-El-Gueiss [Geology and water problems in Algeria. T. 1: Elements of Technogeology of the Algerian Dams and some annex works – The Foum-El-Gueiss Dam]. Vol. 1. XIXe congrès géologique international p. 251–258.
- LI P., TIAN R., XUE C., WU J. 2017. Progress, opportunities and key fields for groundwater quaresearch under the impacts of human activities in China with a special focus on western China. Environmental Science and Pollution Research. Vol. 24(15) p. 13224–13234. DOI 10.1007/s11356-017-8753-7.
- LIU F., SONG X., YANG L., HAN D., ZHANG Y., MA Y., BU H. 2015. The role of anthropogenic and natural factors in shaping the geochemical evolution of groundwater in the Subei Lake basin, Ordos energy base, Northwestern China. Science of The Total Environment. Vol. 538 p. 327–340. DOI 10.1016/j.scitotenv.2015.08.057.
- MA B., JIN M., LIANG X., LI J. 2017. Groundwater mixing and mineralization processes in a mountain–oasis–desert basin, northwest China: Hydrogeochemistry and environmental tracer indicators. Hydrogeology Journal. Vol. 26(1) p. 233–250. DOI 10.1007/s10040-017-1659-0.
- MONITION L. 1966. Les graphiques a base trilineaire représentatifs de la composition chimique des eaux souterraines. Le diagramme en “losange” [The trilinear graphs are representative of the chemical composition of groundwater. The “diamond” diagram]. Bureau de recherches géologiques et minières, Direction scientifique département géologie Service d’hydrogéologie pp. 22.
- MOSAAD S., EL ABD EL S.A., KEHEW A.E. 2019. Integration of geochemical data to assess the groundwater quality in a carbonate aquifer in the southeast of Beni-Suef city, Egypt. Journal of African Earth Sciences. Vol. 158, 103558. DOI 10.1016/j.jafrearsci .2019.103558.
- ONM 2018. National Weather Office, Climatic data archives. National Meteorological Office of Algeria.
- PIPER A.M. 1953. A graphic representation in the geochemical interpretation of groundwater analyses. American Geophysical Union Transactions. Vol. 25 p. 914–923.
- REJSEK F. 2002. Analyse des eaux – Aspects réglementaires et techniques [Water analysis – regulatory and technical aspects]. Paris. Sceren. ISBN 9782866174200 pp. 360.
- RIEDEL T. 2019. Temperature-associated changes in groundwater quality. Journal of Hydrology. Vol. 572 p. 206–212. DOI 10.1016/j.jhydrol.2019.02.059.
- RODIER J., LEGUBE B., MERLET N., BRUNET R. 2009. L’analyse de l’eau : Eaux naturelles, eaux résiduaires, eau de mer [Analysis of water: Natural water, wastewater, seawater]. 9th ed. Paris. Dunod. ISBN 978-2100072460 pp. 1600.
- SARAVANAN K., SRINIVASAMOORTHY K., GOPINATH S., PRAKASH R., SUMA C.S. 2016. Investigation of hydrogeochemical processes and ground-water quality in Upper Vellar sub-basin Tamilnadu, India. Arabian Journal of Geosciences. Vol. 9(5), 372.
- SELVAKUMAR S., CHANDRASEKAR N., KUMAR G. 2017. Hydrogeochemical characteristics and groundwater contamination in the rapid urban development areas of Coimbatore, India. Water Re-sources and Industry. Vol. 17 p. 26–33. DOI 10.1016/j.wri.2017.02.002.
- THILAGAVATHI R., CHIDAMBARAM S., PRASANNA M.V., THIVYA C., SINGARAJA C. 2012. A study on groundwater geochemistry and water quality in layered aquifers system of Pondicherry region, southeast India. Applied Water Science. Vol. 2 p. 253–269. DOI 10.1007/s13201-012-0045-2.
- WAGH V.M., PANASKAR D.B., VARADE A.M., MUKATE S.V., GAIKWAD S.K., PAWAR R.S., MULEY A.A., AAMALAWAR M.L. 2016. Major ion chemistry and quality assessment of the groundwater resources of Nanded tehsil, a part of southeast Deccan Volcanic Province, Maharashtra, India. Environmental Earth Sciences. Vol. 75, 1418. DOI 10.1007/s712665-016-6212-2.
- ZHOU Y., WEI A., LI J., YAN L., LI J. 2016. Groundwater quality evaluation and health risk assessment in the Yinchuan region, northwest China. Exposure and Health. Vol. 8(3) p. 443–456. DOI 10.1007/s12403-016-0219-5.
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-17215d17-ec49-4ac1-bc67-eb4efd833d60