Abstract
Chemical properties and hydrogeological characterization of water resources were studied in the Hammemt Plain, which is located in the northwest of the Tezbent mountain range, City of Tébessa, northeast of Algeria, which drains carbonate aquifers through various large karst springs. The physical and chemical characteristics of spring and well water samples were studied for 2 years in order to assess the origin of groundwater and determine the factors driving its geochemical composition. The ionic speciation and mineral dissolution/precipitation were calculated where we found that water wells, characterizing groundwater circulation at shallow depths, are moderate to highly mineralized waters of the Na-HCO3 type. In contrast to the shallow environment, the CO2-rich, deeper waters are of the Ca-HCO3 type, and undergo significant changes in their baseline chemistry along flow lines with increasing residence time. The main factors controlling the groundwater composition and its seasonal variations are geology, because of the presence of different carbonate formations, additionally elevation, and the rate of karst development. Supersaturation with respect to calcite indicates CO2 degasing occurs either inside the aquifer in open conduits or at the outlet in reservoirs. Undersaturation with respect to calcite shows the existence of fast flow and short residence-time conditions inside the aquifer. The main springs and wells of the Tazbent Mountain have been studied by means of stable isotope measurement, where the values are varied in 18O; between −8.2 and −7.76 for spring samples and from −8.26 to −7.15 for well samples and in 2H between −52.92 and −49.11 for spring samples and from −55.47 to −47.44 for well samples, showing that the groundwater recharge is of meteoric origin and suggests the absence of the evaporation effect on the isotopic composition.
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References
Ademoroti CMA (1996) Standard methods for water and effluents analysis. Fodulex Press Ltd, Ibadan, pp 32–34
APHA (1999) Standard methods for the examination of water and wastewater. 20th ect. APHA, AWWA, WPCF, New York
Appelo C, Williemsen A, Beekmanhe Grippioen (1999) Calculations and observations on salt water intrusion, II. Validation of a geochemical model with laboratory experiments. J Hydrol 120:225–250
Araguas LJ, Diaz Teijeiro MF (2005) Isotope composition of precipitation and water vapour in the Iberian Peninsula: first results of the Spanish network of isotopes in precipitation. In: international atomic energy agency—isotopic composition of precipitation in the Mediterranean Basin in relation to air circulation patterns and climate. Int At Energy Agency 1453:173–190
Bakalowicz M (2005) Karst groundwater: a challenge for new resources. J Hydrol 13:148–160
Bonacci O, Pipan T, Culver DC (2009) A framework for karst ecohydrology. Environ Geol 56:891–900
Celle JH, Zouari K, Travi Y, Daoued A (2001) Caractérisation isotopique des pluies en Tunisie. Essai de typologie dans la région de Sfax. C.R. Acad. Sci Paris Sci de la Terre et des Planètes 333:625–631
Craig H (1961) Standard for representing concentrations of deuterium and oxygcn-18 in natural waters. Science 133:1833–1834
Deby and Huckel (1923) Zur Theorie der Elektrolyte. I. Gefrierpunktserniedrigung und verwandte Erscheinungen [The theory of electrolytes. I. Lowering of freezing point and related phenomena] Physikalische Zeitschrift 24:185–206
Djabri L (1987) Contribution to the hydrogeological study of the subsidence plain of Tebessa NE Algeria. Attempt of modeling. Doctorate Thesis, University of Franche Comté, France
Fehdi Ch, Aek Rouabhia, Baali F (2008) The Hydrogeochemical characterization of Morsott-El Aouinet aquifer. Environmental Geology, Springer-Verlag, Berlin; Heidelberg, Northeastern Algeria. doi:10.1007/s00254-008-1667-4
Fehdi C, Baali F, Boubaya D, Rouabhia A (2011) Detection of the sinkholes using 2D electrical resistivity imagining in the Cheria Basin(north east of Algeria. Arab J Geosci 4:181–187
Fontes J (1980): Environmental isotopes in ground water hydrology. In: Fritz J, Fontes J (eds) Handbook of environmental isotope geochemistry. Elsevier, Amsterdam, l (A):75
Fontes JCh, Yousfi M, Allison GB (1986) Estimation of long term, diffuse groundwater discharge in the northern Sahara using stable isotope profiles in soil water. J Hydrol 86:315–327
Gat J, Carmi L (1970) Evolution of the isotopic composition of atmospheric waters in the Mediterranean Sea area. J Geophys Res 75:3039–3048
Goldscheider N, Drew D (2007) Methods in Karst hydrogeology. Taylor & Francis, London, p 264
Liana M et al. (2014) Groundwater geochemistry observations in littoral caves of Mallorca (western Mediterranean): implications for deposition of phreatic overgrowths on speleothems
Olajire AA, Imeokparia FE (2001) Water quality assessment of Osun river: studies on inorganic nutrients. Environ Monit Assess 69(1):17–28
Piper AM (1944) A graphic procedure in geochemical interpretation of water analysis. Trans Amer Geophys Union, 25(6):914–928; Richmond,VA
Ravbar N (2007) The protection of karst waters. Carso-logica 6. ZRC publishing, Postojna-Ljubljana, p 254
Ravbar N, Kova G (2006) Karst water management in Slovenia in the frame of vulnerability map ping. Acta Carsologica, Ljubljana, pp 35–2
Rouabhia Aek, Baali F, Fehdi Ch (2009) Impact of agricultural activity and lithology on groundwater quality in the Merdja area, Tebessa, Algeria. Arab J Geosci, Springer-Verlag, Berlin; Heidlerg. doi 10.1007/12517-009-0087-4
Salameh E (2001) Sources of water salinities in the Jordan Valley Area. Jordan Acta hydrochim hydrobiol 6–7:329–362
Simler R (2004) Hydrochemistry Software multilanguage free distribution. Hydrogeology Laboratory of Avignon, Version 2
Vila JM (1980) La chaîne alpine de l’Algérie orientale et des confins Algéro-Tunisiens. Thèse de Doctorat- es -sciences, Université Pierre et Marie curie, Paris VI
Wilcox L (1948) The quality of water for agricultural use. US Dept Agriculture, Tech Bull 962, Washington DC
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The authors acknowledge the co-operation of the Laboratory of Water and Environment of Tébessa University for their participation in some of the analytical programs. Authors wishes to give special thanks to Prof Elias Salameh of Jordan University, Department of Geology.
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Chemseddine, F., Dalila, B. & Fethi, B. Characterization of the main karst aquifers of the Tezbent Plateau, Tebessa Region, Northeast of Algeria, based on hydrogeochemical and isotopic data. Environ Earth Sci 74, 241–250 (2015). https://doi.org/10.1007/s12665-015-4480-x
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DOI: https://doi.org/10.1007/s12665-015-4480-x