Abstract
Deterioration in the groundwater quality is prevalent in many parts of the eastern and north-eastern India; however, little attention has been paid for its assessment. In order to evaluate the groundwater suitability in the north-eastern region of India, this study was carried out in Barpeta District of Assam. The groundwater samples were collected from various locations to represent the overall water quality of the district. Suitability was assessed in terms of its usability for drinking and irrigation. It was found that the groundwater samples are contaminated with high amount of arsenic, which refers that water is unfit for consumption as well as agricultural activities. Hydrogeological studies revealed that regional geological factors might be responsible for excess arsenic concentration in the region. Overall, groundwater quality was found to be alkaline having moderate hardness with high amount of iron, manganese, and lead as well.
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Aghazadeh, N., & Mogaddam, A. A. (2010). Assessment of groundwater quality and its suitability for drinking and agricultural uses in the Oshnavieh area, northwest of Iran. Journal of Environmental Protection, 1, 30–40.
Al-Tabbal, J. A., & Al-Zboon, K. K. (2012). Suitability assessment of groundwater for irrigation and drinking purpose in the northern region of Jordon. Journal of Environmental Science and Technology, 5(5), 274–290.
APHA. (1992). Standard methods for the examination of water and waste waters (18th ed.). Washington, DC: American Public Health Association.
BIS. (2012). Specifications for drinking water. Is: 10500:2012. New Delhi: Bureau of Indian Standards.
Bissen, M., & Frimmel, F. H. (2003). Arsenic: a review – part I – occurrence, toxicity, speciation, mobility. Acta Hydrochimica et Hydrobiologica, 31, 9–18.
Buragohain, M., Bhuyan, B., & Sarma, H. P. (2010). Seasonal variation of lead, arsenic, cadmium, and aluminium contamination of groundwater in Dhemaji district, Assam, India. Environmental Monitoring and Assessment, 170, 345–351.
Chadha, D. K. (1999). A proposed new diagram for geochemical classification of natural waters and interpretation of chemical data. Hydrogeology Journal, 7, 431–439.
Chetia, M., Chatterjee, S., Banerjee, S., Nath, M. J., Singh, L., Srivastava, R. B., & Sarma, H. P. (2011). Groundwater arsenic contamination in Brahmaputra river basin: A water quality assessment in Golaghat (Assam), India. Environmental Monitoring and Assessment, 173, 371–385.
CPCB Report (2015). River stretches for restoration of water quality. MINARS/37/2014–15.
Davenport, J. R., & Peryea, F. J. (1991). Phosphate fertilizers influence leaching of lead and arsenic in a soil contaminated with lead arsenate. Water, Air, and Soil Pollution, 57(1), 101–110.
District Census Handbook, Barpeta (2011). Directorate of census operations, series 19, Part XII-A, Assam.
Doneen, I.D. (1961). The influence of crop and soil on percolating water. Proceedings of Biannual Conference on Groundwater Recharge 1961, 156–163.
Eaton, F. M. (1950). Significance of carbonates in irrigation waters. Soil Science, 69(2), 123–134.
Gibbs, R. J. (1970). Mechanisms controlling world water chemistry. Science, 170(3962), 1088–1090.
Government of India (2017). Dream of ‘Har Ghar Jal’ will be realized by 2030. Resource document. Press Information Bureau, 22 March 2017. http://pib.nic.in/newsite/PrintRelease.aspx?relid=159709. Accessed 13 December 2017.
Higgins, C. G., & Coates, D. R. (1990). Groundwater geomorphology: the role of subsurface water in earth-surface processes and landforms, issue 252. Boulder: Geological Society of America.
Hiscock, K. M. (2009). Hydrogeology: principles and practice. Hoboken: Wiley-Blackwell.
Ishaku, J. M., Ahmed, A. S., & Abubakar, M. A. (2011). Assessment of groundwater quality using chemical indices and GIS mapping in Jada area, northeastern Nigeria. Journal of Earth Sciences and Geotechnical Engineering, 1(1), 35–60.
Jain, C. K., & Bhatia, K. K. S. (1988). Physico-chemical analysis of water and wastewater, user’s manual. Roorkee: UM-26, National Institute of Hydrology.
Karanth, K. R. (1987). Groundwater assessment, development and management. New Delhi: Tata-McGraw- Hill Education.
Katz, B. G., Tyler, B. C., Thomas, D. B., & Davis, J. H. (1997). Use of chemical and isotopic tracers to characterize the interactions between groundwater and surface water in mantled karst. Ground Water, 35(6), 1014–1028.
Kelly, W. P., Brown, S. M., & Liebig, G. F. (1940). Chemical effects of saline irrigation water on soils. Soil Science, 49(2), 95–108.
Kumar, M., Kumari, K., Ramanathan, A. L., & Saxena, R. (2007). A comparative evaluation of groundwater suitability for irrigation and drinking purposes in two intensively cultivated districts of Punjab, India. Environmental Geology, 53, 553–574.
Lloyd, J.W. & Heathcote, J.A. (1985). Natural inorganic hydrochemistry in relation to groundwater. University of Wisconsin – Madison: Oxford Science Publications.
Matschullat, J. (2000). Arsenic in the geosphere – A review. The Science of the Total Environment, 249, 297–312.
Mayo, A. L., & Loucks, M. D. (1995). Solute and isotopic geochemistry and groundwater flow in the central Wasatch range, Utah. Journal of Hydrology, 172, 31–59.
Nag, S. K., & Das, S. (2014). Quality assessment of groundwater with special emphasis on irrigation and domestic suitability in Suri I & II blocks, Birbhum district, West Bengal, India. American Journal of Water Resources, 2(4), 81–98.
Piper, A. M. (1944). A graphical procedure in the geochemical interpretation of water analysis. Transactions - American Geophysical Union, 25, 914–928.
Polizzotto, M. L., Harvey, C. F., Li, G., Badruzzman, B., Ali, A., Newville, M., Sutton, S., & Fendrof, S. (2006). Solid-phases and desorption processes of arsenic within Bangladesh sediments. Chemical Geology, 228, 97–111.
Rajmohan, N., & Elango, L. (2006). Hydrogeochemistry and its relation to groundwater level fluctuation in the Palar and Cheyyar river basins, southern India. Hydrological Processes, 20, 2415–2427.
Richards, L. A. (1954). Diagnosis and improvement of saline and alkali soils. Agricultural handbook no. 60. Washington DC: United States Department of Agriculture.
Sarin, M. M., Krishnaswami, S., Dilli, K., Somayajulu, B. L. K., & Moore, W. S. (1989). Major ion chemistry of the ganga – Brahmaputra river systems: Weathering processes and fluxex to the bay of Bengal. Geochimica et Cosmochimica Acta, 53, 997–1009.
Sawid, F. A., & Issa, A. A. (2015). Assessment of groundwater quality for drinking and irrigation purposes, Martubah plain, eastern Libya. WIT Transactions on Ecology and the Environment, 196, 311–325.
Schoeller, H. (1967). Geochemistry of groundwater. An international guide for research and practice. UNESCO, Chapter 15, pp 1–18.
Smedley, P.L. & Kinniburgh, D.G. (2003). Source and behaviour of arsenic in natural waters. In: Arsenic in drinking water. World Health Organization.
Smith, A. H., Hopenhayn-Rich, C., Bates, M. N., Goeden, H. M., Hertz-Picciotto, I., Duggan, H. M., Wood, R., Kosnett, M. J., & Smith, M. T. (1992). Cancer risks from arsenic in drinking water. Environmental Health Perspectives, 97, 259–267.
Subramanian, V., & Ramanathan, A. L. (1996). Nature of sediment load in the Ganges-Brahmaputra River systems in India. In J. D. Milliman & B. U. Haq (Eds.), Sea-level rise and coastal subsidence, Coastal Systems and Continental Margins (Vol. 2, pp. 151–168). Dordrecht: Springer.
Szabolcs, I., & Darab, C. (1964). The influence of irrigation water of high sodium carbonate content of soils. Proceedings of 8th International Congress of ISSS, Transmission, 2, 803–812.
Tripathi, A. K., Mishra, U. K., Mishra, A., Tiwari, S., & Dubey, P. (2012). Studies of hydrogeochemical in groundwater quality around Chakghat area, Rewa District, Madhya Pradesh, India. International Journal of Modern Engineering Research, 2(6), 4051–4059.
World Bank Report (2012), available at http://www.worldbank.org/en/news/feature/2012/03/06/india-groundwater-critical-diminishing. Accessed Nov 24 2017.
World Health Organization (WHO) (2003). Iron in drinking water, background document for development of WHO guidelines for drinking water quality. WHO/SDE/WSH/03.04/08.
World Health Organization (WHO) (2011). Manganese in drinking water, background document for development of WHO guidelines for drinking water quality. WHO/SDE/WSH/03.04/104/Rev/1.
Yan, X. P., Kerrich, R., & Hendry, M. J. (2000). Distribution of arsenic(III), arsenic(V) and total inorganic arsenic in porewaters from a thick till and clay-rich aquitard sequence, Saskatchewan, Canada. Geochimica et Cosmochimica Acta, 62(15), 2637–2648.
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Jain, C.K., Sharma, S.K. & Singh, S. Physico-chemical characteristics and hydrogeological mechanisms in groundwater with special reference to arsenic contamination in Barpeta District, Assam (India). Environ Monit Assess 190, 417 (2018). https://doi.org/10.1007/s10661-018-6781-5
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DOI: https://doi.org/10.1007/s10661-018-6781-5