JEP> Vol.1 No.1, March 2010

Assessment of Groundwater Quality and its Suitability for Drinking and Agricultural Uses in the Oshnavieh Area, Northwest of Iran

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ABSTRACT

The Oshnavieh plain is part of the West Azarbaijan province, which is located; 100 km south of Urmia City, northwestern of Iran, and its groundwater resources are developed for water supply and irrigation purposes. In order to evaluate the quality of groundwater in study area, 31 groundwater samples were collected and analyzed for various parameters. Physical and chemical parameters of groundwater such as electrical conductivity, pH, total dissolved solids, Na, K, Ca, Mg, Cl, HCO3, CO3, SO4, NO3, NH3, PO4, Fe, F were determined. Chemical index like percentage of sodium, sodium ad-sorption ratio, and residual sodium carbonated, permeability index (PI) and chloroalkaline indices were calculated. Based on the analytical results, groundwater in the area is generally fresh and hard to very hard. The abundance of the major ions is as follows: HCO3 > SO4 > Cl and Ca > Mg > Na > K. The dominant hydrochemical facieses of groundwater is Ca-HCO3 and Ca-Mg-HCO3 type. According to Gibbs diagrams samples fall in the rock dominance field and the chemical quality of groundwater is related to the lithology of the area. The results of calculation saturation index by computer pro-gram PHREEQC shows that the nearly all of the water samples were saturated to undersaturated with respect to carbon-ate minerals and undersaturated with respect to sulfate minerals. Assessment of water samples from various methods in-dicated that groundwater in study area is chemically suitable for drinking and agricultural uses. Fluoride and nitrate are within the permissible limits for human consumption and crops as per the international standards.

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N. Aghazadeh and A. Mogaddam, "Assessment of Groundwater Quality and its Suitability for Drinking and Agricultural Uses in the Oshnavieh Area, Northwest of Iran," Journal of Environmental Protection, Vol. 1 No. 1, 2010, pp. 30-40. doi: 10.4236/jep.2010.11005.

References

[1] P. A. Domenico and F. W. Schwartz, “Physical and chemical hydrogeology,” John Wiley and Sons, New York, pp. 824, 1990.
[2] R. A. Freeze and J. A. Cherry, “Groundwater,” Pren-tice-Hall, Englewood Cliffs, NJ, USA, 1979.
[3] B. K. Kortatsi, “Hydrochemical framework of groundwa-ter in the Ankobra Basin, Ghana,” Aquatic Geochemistry, Vol. 13, No. 1, pp. 41–74, 2007.
[4] Z. Barkic, et al., “Hydrogeology and hydrogeochemistry in the alluvial aquifer of the Zagreb area (Croatia),” Ma-terials and Geoenvironment, Vol. 50, No. 1, pp. 75–78. 2003.
[5] A. Elkrai1, O. Kheir, L. Shu, and H. Zhenchun, “Hydro-geology of the northern Gezira area, central Sudan,” Jour-nal of Spatial Hydrology, Vol. 4, No. 2, pp. 11, 2004.
[6] N. Aghazadeh and A. A. Mogadam, “Evaluation effect of geological formation on groundwater quality in the Har-zandat plain aquifer,” Symposium of Geosciences of Iran, Vol. 22, pp. 392–395, 2004.
[7] M. T. Hossien, “Hydrochemical evaluation of groundwa-ter in the Blue Nile Basin, eastern Sudan, using conven-tional and multivariate techniques,” Hydrogeology Jour-nal, Vol. 12, pp. 144–158, 2004.
[8] M. A. Schiavo, S. Havser, G. Gusimano, and L. Gatto, “Geochemical characterization of groundwater and sub-marine discharge in the south-eastern Sicily,” Continental Shelf Research, Vol. 26, No. 7, pp. 826–834, 2006.
[9] T. Subramani, L. Elango, and S. R. Damodarasamy, “Groundwater quality and its suitability for drinking and agricultural use in Chithar River Basin, Tamil Nadu, In-dia,” Environmental Geology, Vol. 47, pp. 1099–1110, 2005.
[10] C. Guler and G. D. Thyne, “Hydrologic and geologic factors controlling surface and groundwater chemistry in Indian Wells-Owens Valley area, southeastern California, USA,” Journal of Hydrology, Vol. 285, pp. 177–198, 2004.
[11] E. Vazquez Sunne, X. Sanchez Vila, and J. Carrera, “In-troductory review of specific factors influencing urban groundwater, an emerging branch of hydrogeology, with reference to Barcelona, Spain,” Hydrogeology Journal, Vol. 13, pp. 522–533, 2005.
[12] A. Moghaddam and M. Najib, “Hydrogeologic character-istics of the alluvial tuff aquifer of northern Sahand Mountain slopes, Tabriz, Iran,” Hydrogeology Journal, Vol. 14, pp. 1319–1329, 2006.
[13] M. Jalali, “Chemical characteristics of groundwater in parts of mountainous region, Alvand, Hamadan, Iran,” Environmental Geology, Vol. 51, pp. 433–446, 2006. E. Khazaei, J. D. Stednick, W. E. Sanford, and J. W. Warner,
[14] “Hydrochemical changes over time in the Za-hedan aquifer, Iran,” Environmental Monitoring and As-sessment, 2006.
[15] J. D. Hem, “Study and interpretation of the chemical characteristics of natural water,” US Geological Survey Water-Supply Paper, 1970.
[16] H. Schoeller, “Geochemistry of groundwater. An interna-tional guide for research and practice,” UNESCO, Chap-ter 15, pp. 1–18, 1967.
[17] APHA, “Standard methods for the examination of water and wastewater,” 19th Edition, American Public Health Association. Washington, D.C., pp. 1467, 1995.
[18] D. L. Parkhurst and C. A. J. Appelo, “User’s guide to PHREEQC (ver. 2)-A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations,” US Geological Survey Wa-ter-Resources Investment Report, pp. 99–4259, 1999.
[19] M. H. Nabavi, “Preface geology of Iran,” (in Persian), Geology Survey Iran, 1976.
[20] A. Aghanabati, “Geology of Iran,” (in Persian), Geologi-cal Survey of Iran, pp. 586, 2004.
[21] N. Aghazadeh, “Evaluation quality and quantity ground-water of the Oshnavieh plain aquifer,” (in Persian), Is-lamic Azad University of Urmia, Iran, pp. 128, 2007.
[22] Azarbaijan Regional Water Authority, “Evalution of groundwater in Oshnavieh and Naghadeh plain,” (in Per-sian) Azarbaijan Regional Water Authority, Urmia, Iran, 2004.
[23] C., A., J. Appelo and D. Postma, “Geochemistry, ground-water and pollution,” Balkema, Rotterdam, pp. 536, 1996.
[24] A. Bardsen, et al., “Variability in fluoride content of sub-surface water reservoirs,” Acta Odontologica Scandi-navica, Vol. 54, pp. 343–347, 1996.
[25] W. W. Wenzel and W. E. H. Blum, “Fluoride speciation and mobility in fluoride contaminated soil and minerals,” Journal of Soil Science, Vol. 153, pp. 357–364, 1992.
[26] R. J. Gibbs, “Mechanisms controlling world water chem-istry,” Science, Vol. 17, pp. 1088–1090, 1970.
[27] M. Coetsiers and K. Walraevens, “Chemical characteriza-tion of the Neogene Aquifer, Belgium,” Hydrogeology Journal, Vol. 14, pp. 1556–1568, 2006.
[28] J. I. Drever, “The geochemistry of natural waters,” Pren-tice-Hall, New Jersey, pp. 436, 1997.
[29] D. Langmuir, “Aqueous environmental geochemistry,” Prentice Hall, Inc., pp. 601, 1997.
[30] R. Garrels and F. Mackenzie, “Origin of the chemical compositions of some springs and lakes,” In: Ground RF (ed) Equilibrium Concepts in Natural Water Systems, Ameri-can Chemical Society Publications, Washington, 1967.
[31] A. M. Piper, “A graphic procedure in the geochemical interpretation of water-analyses,” Transactions, American Geophysical Union, Vol. 25, pp. 914–923, 1944.
[32] D. K. Chadha, “A proposed new diagram for geochemical classification of natural water and interpretation of chemical data,” Hydrogeology Journal, Vol. 7, pp. 431– 439, 1999.
[33] WHO, “Guideline to drinking water quality,” World Health Organization, Geneva, pp. 186, 1983.
[34] WHO, “Guidelines for drinking water quality,” Recommenda-tions, World Health Organization, Geneva, Vol. 1, pp. 130, 1984.
[35] G. N. Sawyer and D. L. McCartly, “Chemistry of sanitary engineers,” 2nd ed., McGraw Hill, New York, pp. 518, 1967.
[36] S. Srinivasa Gowd, “Assessment of groundwater quality for drinking and irrigation purpose: A case study of Ped-davanka watershed, Anantapur District, Andhra Pradesh, India,” Environmental Geology, Vol. 48, pp. 702–712. 2005.
[37] N. J. Raju, “Hydrogeochemical parameters for assessment of groundwater quality in the upper Gunjanaeru River ba-sin, Cuddapah District, Andhara Pradesh, South India,” Environmental Geology; 2006.
[38] US Salinity Laboratory, “Diagnosis and improvement of saline and alkali soils,” Agricultural Handbook, USDA, No. 60, pp. 160, 1954.
[39] K. R. Karanth, “Groundwater assessment, development and management,” Tata McGraw Hill, New Delhi, pp. 720, 1987.
[40] L. A. Richards, “Diagnosis and improvement of saline alkali soils: Agriculture,” Handbook, US Department of Agriculture, Washington DC, Vol. 160, pp. 60, 1954.
[41] L. V. Wilcox, “Classification and use of irrigation water,” USDA, Circular, Washington, DC, USA, pp. 969, 1955.
[42] F. M. Eaton, “Significance of carbonate in irrigation wa-ter,” Soil Science, Vol. 69, No. 2, pp. 123–133, 1950.
[43] H. M. Ragunath, “Groundwater,” Wiley Eastern Ltd., New Delhi, pp. 563, 1987.
[44] WHO, “Health guidelines for the use of wastewater in agriculture and aquaculture,” Report of a WHO Scientific Group-Techni-cal Report Series 778, WHO Geneva, pp. 74, 1989.
[45] J. C. V. Aastri, “Groundwater chemical quality in river basins, hydrogeochemical facies and hydrogeochemical modeling,” Bharathidasan University, Thiruchirapalli, Tamil Nadu, India, 1994.
[46] H. Schoeller, “Geochemistry of groundwater,” In: Groundwater Studies-An International Guide for Re-search and Practice, UNESCO, Paris, pp. 1–18, 1977.

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