Abstract
The present study investigates the physical, chemical, and biological characteristics of spring water samples in Shoubak area in the southern Jordan. The samples were collected from May 2004 to May 2005. All samples were analyzed for temperature, conductivity, dissolved oxygen, pH, major cations (Ca2+, Mg2+, K+, Na+), major anions (Cl−, NO −3 , HCO −3 , SO 2−4 , PO 3−4 , F−), and trace metals (Fe2+, Al3+, Mn2+, Cu2+, Cr3+, Ni2+, Zn2+, Pb2+, Cd2+). Water quality for available springs showed high salinity through long period of contact with rocks. The ion concentrations in the water samples were from dissolution of carbonate rocks and ion exchange processes in clay. The general chemistry of water samples was typically of alkaline earth waters with prevailing bicarbonate chloride. Some springs showed elevated nitrate and sulfate contents which could reflect to percolation from septic tanks, cesspools, and agricultural practices. The infiltration of wastewater from cesspools and septic tanks into groundwater is considered the major source of water pollution. The results showed that there were great variations among the analyzed samples with respect to their physical, chemical and biological parameters, which lie below the maximum permissible levels of the Jordanian and WHO drinking water standards. The results indicate that the trace metals of spring’s water of Shoubak area do not generally pose any health or environmental problems. Factor analysis was used to identify the contributers to water quality. The first factor represents major contribution from anthropogenic activities, while the second one represents major contribution from natural processes.
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References
Al-Awadi, E., Mukhopadhay, A., Akber K, & Hadi, K. (2003). Distribution of selected trace constituents in the groundwater of Kuwait. Advanced Environmental Research, 7, 367–380.
Al-Kharabsheh, A., & Ta’any, R. (2003). Influence of urbanization on water quality deterioration during drought periods at south Jordan. Journal of Arid Environments, 53, 619–630.
Al-Khashman, O. (2002). Environmental status of the area extending between Wadi El-Hasa and wadi Musa from the railway to Wadi Araba. PhD thesis, University of Jordan, Amman, Jordan, 177␣pp.
Al-Khashman, O. (2007). Study of water quality of springs in Petra region, Jordan: A three-year follow-up. Water Resources Management, 21(7), 1145–1163.
American Public Health Association. (1992). Standard methods for water and wastewater analysis (18th ed.). New York.
Bender, F. (1974). Geology of Jordan (supplementary edition in English with minor revision). Berlin, Germany, 230 pp.
Carpenter, S. R., Caraco, N. F., Correll, D. L., Howarth, R. W., Sharpley, A. N., & Smith, V. H. (1998). Non point of surface waters with phosphorous and nitrogen. Ecological Application, 8(3), 559–568.
Department of Meteorology. (2004). Internal report. Amman, Jordan.
Dojlido, J., & Best, G. (1993). Chemistry of water and water pollution. London, UK.: Ellis-Harwood limited.
Drever, J. F. (1988). The chemistry of natural waters (3rd ed.). Prentice-Hall, New York. Inc, 388 pp.
Fetter, C. W. (1988). Applied hydrogeology (2nd ed., pp. 592). London: Merrill publishing company.
Japan International Cooperation Agency (JICA). (1995). The study on brackish groundwater desalination in Jordan-Yachiyo Engineering Co. Ltd, Tokyo, Japan, 318 p.
Jarvie, H. P., Whitton, B. A., & Neal, C. (1998). Nitrogen and phosphorous in east coast British rivers: Speciation, sources and␣biological significant. Science of the Total environment, 210–211, 79–109.
Jeong, C. H. (2003). Effect of landuse and urbanization on hydrochemistry and contamination of ground water from Taejon area, Korea. Journal of Hydrology, 235, 194–210.
Jordan Standards. (2003). Jordanian Standards for drinking water. Ministry of water and irrigation, Amman, Jordan.
Langguth, H. R. (1966). Groundwater verhaltisse in Bereiech Des Velberter. Sattles. Der Minister Fur Eraehrung, Land Wirtsch Forste (pp. 127). Duesseldorf: NRW.
Larsen, D., Swihart, G. H., & Xiao, Y. (2001). Hydrochemistry and isotope composition of springs in the Tecopa basin, southeastern California, USA. Chemical geology, 179, 17–35.
Macdonald, M. (1965). Hydrogeological survey of the Madaba-Ma’an area (Vol. 2, pp. 30). Jordan: Report at the Water Authority of Jordan, Amman.
Magaritz, M., Aravena, R., Pena, H., Suzuki, O., & Grill, A. (1989). Water chemistry and isotope study of streams and springs in northern Chile. Journal of Hydrology, 108, 323–341.
Mercado, A. (1985). The use of hydrochemical pattern in carbonate, sand and sandstone aquifers to identify intrusion and flushing of saline water. Groundwater, 23, 335–344.
Mouli, P., Mohan, S. V., & Reddy, S. J. (2005). Rainwater chemistry at a regional representative urban site: Influence of terrestrial sources on ionic composition. Atmospheric Environment, 39, 999–1008.
Piper, A. M. A. (1953). Graphic procedure in the geochemical interpretation of water analysis. Groundwater Note 12. United State Geological Survey.
Powell, J. H. (1989). Stratigraphy and sedimentation of the phanerozoic rocks in central and south Jordan; Part B, Kurnub, Ajlun and Belqa groups. Geol. Mapping Div. Bull. 11A, Natural Resources Authority, Amman, Jordan, 130 pp.
Rand, M., Greenberg, A., & Taras, M. (1995). Standard methods for examination of water and wastewater (19th ed. pp. 113). Washington, D.C. USA: American Public Health Association.
Ritzi, R. W., Wright, S. L., Mann, B., & Chen, M. (1993). Analysis of temporal variability in hydrogeochemical data used for multivariate analysis. Groundwater, 31, 221–229.
Sahawneh, J., Swarieh, A., & Masarweh, R. (2000). Geology and hydrogeology of the northern Wadi Araba basin. Natural Resources Authority, Internal report, No. 11. Amman, Jordan, 88 pp.
Salameh, E., & Udluft, P. (1985). The Hydrodynamic pattern of central Jordan. Geological Journal. C38, 39–53. Hanover.
Salameh, E. (1996). Water quality degradation in Jordan (pp. 179). Amman, Jordan: Royal Society for the Conservation of Nature and Freidrich Ebert Stiftung.
Sawyer, C. N., & McCarty, P. L. (1967). Chemistry and sanitary Engineers (2nd ed.). New York: McGraw-Hill.
Shatanawi, M., & Fayyad, M. (1996). Effect of Khirbet As-Samra treated effluent on the quality of irrigation water in the central Jordan valley. Water Research, 30(12), 2915–2920.
Simeonov, V., Stratis, J. A., Samara, C., Zachariadis, G., Voutsa, D., Anthemidis, A., Sofoniou, M., & Kouimtzis, Th. (2003). Assessment of the surface water quality in Northern Greece. Water Research, 37, 4119–4124.
Subyani, A. M. (2005). Hydrochemical identification and salinity problem of groundwater in Wadi Yalamlam basin Western Saudi Arabia. Journal of Arid Environments, 60, 53–66.
Virkutyte, J., & Sillanpåå, M. (2005). Chemical evaluation of potable water in Eastern Qinghai Province, China: Human health aspects. Environmental International. (In press).
WHO. (2004). Guidelines for drinking water quality (3rd ed.). Geneva, Switzerland: WHO.
WAJ Files. (2003). Water Authority of Jordan Files, Amman, Jordan.
World Heath Organization. (1996). Guidelines for drinking water quality (2nd ed, Vol. 2). Geneva.
Zacheus, O. M., & Martikainen, P. J. (1997). Physicochemical quality of drinking and hot waters in Finnish building originated from groundwater or surface water plants. Science of the Total Environment, 204, 1–10.
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Al-Khashman, O.A. Assessment of the spring water quality in The Shoubak area, Jordan. Environmentalist 28, 203–215 (2008). https://doi.org/10.1007/s10669-007-9129-1
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DOI: https://doi.org/10.1007/s10669-007-9129-1