Abstract
The Yamuna flood plains spread across the northern part of Indian subcontinent is home to millions of people. The ever-growing population in these plains make it difficult to sustain the demand of freshwater resources. However, the productive aquifers of flood plains could provide solution for these issues. In this context, it is necessary to understand the aquifer characteristics. Thus, the paper attempts to characterize the aquifer in Palla area of the flood plain using integrated approach. Besides, grain size analysis and site-litholog study, the nature of aquifer material was also ascertained from bulk mineralogy of the sediments using X-Ray Diffraction. The aquifer parameters were estimated with help of long duration pumping test data. Moreover, the effect of pumping on salinity variation and hydrochemical facies evolution was also examined. The sand dominant, unconfined aquifer was estimated to have horizontal hydraulic conductivity in the range of 25 m/day and vertical hydraulic conductivity of 6–7 m /day. While the specific yield of the aquifer was estimated in the range of 0.07–0.08. It is observed that under conducive active flood plain environment, the given sand mineralogy at the site does not allow salinity increase in groundwater even after more than a decade of groundwater pumping. In fact, over years, hydrochemical facies have evolved towards Bicarbonate type. These things put together make the active flood plain aquifer a sustainable groundwater resource.
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References
Boulton, N. (1954) The drawdown of the water-table under non-steady conditions near a pumped well in an unconfined formation. Proc. Instit. Civil Engg., v.3(4), pp. 564–579.
Boulton, N. (1963) Analysis of data from non-equilibrium pumping tests allowing for delayed yield from storage. Proc. Instit. Civil Engg., v.26(3), pp. 469–482.
CGWB (1982) Manual: Evaluation of aquifer parameters. Ministry of Irrigation (Govt. of India), 183p.
CGWB (1996) Development and augmentation of ground water resources in national Capital Trrritory of Delhi. Central Ground Water Board, Ministry of Water Resources, (Govt. of India).
CGWB (2006) Hydrogeological framework and ground water management plan of NCT Delhi. Central Ground Water Board.
Chatterjee, R., Gupta, B.K., Mohiddin, S.K., Singh, P.N., Shekhar, S. and Purohit, R. (2009) Dynamic groundwater resources of National Capital Territory, Delhi: assessment, development and management Options. Environ. Earth Sci. Jour., v.59(3), pp. 669–686.
Census (2011) Population Census 2011 Available at: http (accessed on 2nd Nov. 2016)
CWC (2015) Central Water Commission. Available at: http://www. cwc.nic.in/ regionaloffice/delhi/welcome.html (accessed on 2nd Nov. 2016).
DES (2014) Report, Statistical Abstract of Delhi. Directorate of Economics & Statistics, Delhi. Available at:http://www.delhi.gov. in/wps/wcm/connect/f508bc8046667b0e9cf6bcf5a4ed47e7/Stattistical+Abstract+of+Delhi+ 2014.pdf?MOD=AJPERES&lmod=1346796026&CACHEID= f508bc8046667b0e9cf6bcf5a4ed47e7 (accessed on 12.01.2016).
ESD (2015) Report, Economic Survey of Delhi (2014-2015) Planing Department, Govt of NCT of Delhi. Available at http://www. delhi.gov.in/ wps/wcm/connect/DoIT_Planning/planning/economic+survey+of+dehli/ economic+survey+of+delhi+2014+-+2015 (accessed on 07.03.2017)
Kruseman, G.P., De Ridder, N.A., Verweij, J.M. (2000) 2nd edition. Analysis and evaluation of pumping test data (p. 377) Wageningen: ILRI publication.
Kumar, M., Ramanathan, A.L., Keshari, A.K. (2009) Understanding the extent of interactions between groundwater and surface water through major ion chemistry and multivariate statistical techniques. Hydrological Processes, v.23(2), pp. 297–310.
Mukherjee, A., Scanlon, B.R., Fryar, A.E., Saha, D., Ghosh, A., Chowdhuri, S., Mishra, R. (2012) Solute chemistry and arsenic fate in aquifers between the Himalayan foothills and Indian craton (including central Gangetic plain): influence of geology and geomorphology. Geochim. Cosmochim. Acta, v.90, pp. 283–302.
Neuman, S.P. (1972) Theory of flow in unconfined aquifers considering delayed response of the water table. Water Resource Res., v.8(4), pp. 1031–1045. doi:10.1029/WR008i004p01031.
Neuman, S.P. (1973) Supplementary Comments on ‘Theory of flow in unconfined aquifers considering delayed response of the water table’. Water Resource Res. v.9(4), pp. 1102–1103. doi:10.1029/WR009i004p0 1102.
Neuman, S.P. (1974) Effect of partial penetration on flow in unconfined aquifers considering delayed gravity response, Water Resource Res., 10(2): 303–312, doi:10.1029/WR010i002p00303.
Neuman, S.P. (1975) Analysis of pumping test data from anisotropic unconfined aquifers considering delayed gravity response. Water Resources Res., v.11(2), pp.329–342, doi:10.1029/WR011i002p00329.
Neuman, S.P. (1979) Perspective on ‘Delayed yield’. Water Resources Res., v.15(4), pp. 899–908. doi:10.1029/WR015i004p00899.
NIH (2006) Comprehensive and Integrated Hydrological Study of NCT Delhi, Report, National Institute of Hydrology, Roorkee, India.
Rao, S.V.N., Kumar, S., Sinha, S.K. and Shekhar, S. (2006a) An operational model for groundwater pumping at Palla Well Fields. NCT, Delhi, Project Report, Joint study by National Institute of Hydrology, Roorkee and Central Ground Water Board, New Delhi.
Rao, S.V.N., Kumar, S., Shekhar, S. and Chakraborty, D. (2006b) Optimal pumping from skimming wells. Jour. Hydrologic Engg., v.11(5), pp. 464–471.
Rao, S.V.N., Kumar, S., Shekhar, S., Sinha, S.K., Manju, S. (2007) Optimal pumping from skimming wells from the Yamuna river flood plain in North India. Hydrogeol. Jour., v.15, pp. 1157–1167.
Rao, S.V.N., Soni, V. and Shekhar, S. (2014) Non-Invasive flood plain technology for river Yamuna to augment drinking water Supply for Delhi. WAPTECH-2014 (Special Edition of In-house technical journal), WAPCOS, Ministry of Water Resources, Govt. of India. pp. 77–80
Saha, D., Sarangam, S.S., Dwivedi, S.N., Bhartariya, K.G. (2010) Evaluation of hydrogeochemical processes in arsenic-contaminated alluvial aquifers in parts of Mid-Ganga Basin, Bihar, Eastern India. Environ. Earth Sci., v.61(4), pp. 799–811.
Sarkar, A. and Shekhar, S. (2013) An assessment of groundwater quality of lesser contaminated aquifers in North District of Delhi. In Proc. Indian Natl. Sci. Acad., v.79(2), pp. 235–243.
Sarkar, A. and Shekhar, S. (2015) The controls on spatial and temporal variation of hydrochemical facies and major ion chemistry in groundwater of South West District, Delhi India. Environ. Earth Sci., v.74(12), pp. 7783–7791.
Sarkar, A., Ali, S., Kumar, S., Shekhar, S., Rao, S.V.N. (2016) Groundwater Environment in Delhi, India. In: Groundwater Environment in Asian Cities: Concepts, Methods and Case Studies, 1st Edition. Elsevier Inc., Publisher.
Shekhar, S., Singh, S.B. and Romani, S. (2005) The Controls to the Variation in Depth to Fresh/Saline Interface in the Groundwater of Southwest District, NCT, Delhi-a Case Study. Jour. Geol. Soc. India, v.66(1), pp. 17–20.
Shekhar, S. (2006a) An approximate projection of availability of the fresh groundwater resources in the South West district of NCT Delhi, India: a case study. Hydrogeol. Jour., v.14(7), pp. 1330–1338.
Shekhar, S. (2006b) An approach to interpretation of step drawdown tests. Hydrogeol. Jour., v.14(6), pp. 1018–1027.
Shekhar, S. (2007) Report on reappraisal hydrogeological study in North and NorthWest districts of NCT Delhi, Central Ground Water Board, Ministry of water resources, Delhi.
Shekhar, S. and Prasad, R.K. (2009) The groundwater in the Yamuna flood plain of Delhi (India) and the management options. Hydrogeol. Jour., v.17(7), pp. 1557–1560.
Shekhar, S., Purohit, R. and Kaushik, Y.B. (2009) Groundwater management in NCT Delhi. Technical paper included in the special session on Ground water in the 5th Asian Regional Conference of INCID, December 9-11, 2009 held at Vigyan Bhawan, New Delhi, available online at http://www.cgwb.gov.in/documents/papers/INCID.html
Shekhar, S. and Rao, S.V.N. (2010) Groundwater management in Palla well field of Delhi using numerical modelling technique-a case study. Silver Jubilee Publication-II, v.25(3&4), pp. 46–51.
Singh, N., Singh, R.P., Kamal, V., Sen, R., Mukherjee, S. (2015) Assessment of hydrogeochemistry and the quality of groundwater in 24-Parganas districts, West Bengal. Environ. Earth Sci., v.73(1), pp. 375–386.
Sinha, R., Kettanah, Y., Gibling, M.R., Tandon, S.K., Jain, M., Bhattacharjee, P.S., Dasgupta, A.S. and Ghazanfari, P. (2009) Craton-derived alluvium as a major sediment source in the Himalayan Foreland Basin of India. Geol. Soc. Amer. Bull., v.121(11-12), pp. 1596–1610.
Soni, V., Shekhar, S., Singh, D. (2014) Environmental flow for the Yamuna River in Delhi as an example of Monsoon Rivers in India. Curr. Sci., v.106(4), pp. 558–564.
Srivastava, P., Parkash, B. and Pal, D.K. (1998) Clay Minerals in Soils as Evidence of Holocene Climatic Change, Central Indo-Gangetic Plains, North-Central India. Quaternary Res., v.50, pp. 230–239.
Thakur, S. (2016) Characterization of subsurface sediments in Palla well field area of NCT Delhi using qualitative and quantitative approaches, Unpublished M.Sc. dissertation, University of Delhi, Delhi 7.
Theis, C.V. (1935) The relation between the lowering of the piezometric surface and the rate and duration of discharge of a well using groundwater storage. Amer. Geophys. Union Trans., v.16, pp. 519–524.
Thussu, J.L. (2006) Geology of Haryana and Delhi. Geological Society of India, Bangalore, 192p.
Tripathi, J.K., Ghazanfari, P., Rajamani, V., Tandon, S.K. (2007) Geochemistry of sediments of the Ganges alluvial plains: Evidence of large-scale sediment recycling. Quaternary Internat., v.159, pp.119–130
WAPCOS (2012) New research and development (R&D) project for operating Palla group of tube wells in river Yamuna floodplain for sustainable supply of water, submitted to Delhi Jal Board (DJB).
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Kumar, S., Sarkar, A., Thakur, S.K. et al. Hydrogeological characterization of aquifer in palla flood plain of Delhi using integrated approach. J Geol Soc India 90, 459–466 (2017). https://doi.org/10.1007/s12594-017-0739-z
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DOI: https://doi.org/10.1007/s12594-017-0739-z