Abstract
Accurate understanding of a water resource system behavior in response to different stresses is highly essential for designing and implementation of any water resource management decisions. Under this scope, the current research was conducted in lower Ganga-Ramganga interbasin of Uttar Pradesh, India, to study the behavior of water level and the status of groundwater utilization. This study also highlighted the impact of intensive cultivation on groundwater extraction. Contour maps of water level depth were prepared for different seasons, ranging from 1990 to 2012 (23 years), and its trend was studied. The status of water resources in the study area was assessed by analyzing several components of water balance such as daily rainfall, seepage from irrigation water, canal seepage, seepage from tanks and ponds, groundwater use in different sectors (domestic, agriculture and industry) for 23 years. Groundwater inventory was studied in detail, along with varying cropping patterns and irrigation infrastructures. The results indicated that the stage of groundwater utilization in 92% of blocks had shifted from safe, semi-critical, and critical categories to overexploited categories. Over the analyzed period, about 51.47% of the study area had experienced more than 2 m of water level fluctuation. The subsidies on agricultural electricity and water-related infrastructures had caused 24.55% increase in the number of private tube wells, 52.69% increase in the pump set on bore wells, and 12.65% increase in water use during the study period. The study suggests that the groundwater status of the study area is in overexploited stage, and should be a matter of urgent attention; otherwise, it may lead to irreversible and permanent damage to the socio-economic status of a large portion of habitats of the region.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Agricultural Refinance and Development Corporation (ARDC) (1979) Report of ground water over exploitation committee. Mumbai. India, pp 211–232
Badiani R, Jessoe K (2011) Electricity subsidies for agriculture: evaluating the impact and persistence of these subsidies in India. https://www.semanticscholar.org/paper/Electricity-subsidies-for-agriculture-%3A-Evaluating-Badiani-Jessoe/0eb2682bb27429fc27c7d5e52804e1c89f55a3d1. Accessed 28 July 2020
Badiani R, Jessoe KK, Plant S (2012) Development and the environment: the implications of agricultural electricity subsidies in India. J Environ Dev 21(2):244–262
Bhargava DN, Raja RK, Kumar A, Chhabra SS (1983) Evaluation of rainfall recharge to ground water in a part of Gangetic plain by tritium injection method. In: Proceeding of the seminar on assessment development and management of ground water resources, New Delhi, April 29–30, vol II, pp 155–164
Bhattacharjee, BK (1982) Rainfall-recharge correlation; a method for evaluating potential groundwater. In: Proceedings of the exeter symposium on improvements of methods of long term prediction of variations in groundwater resources and regimes due to human activity, Exeter, UK, vol 136. International Association of Hydrological Sciences. July 1982. pp 161–167
Briscoe J, Malik RPS (2006) India’s water economy: bracing for a turbulent future. Oxford University Press, New Delhi
Central Ground Water Board, India (2009) Status report on review of groundwater resources estimation methodology. http://www.indiaenvironmentportal.org.in/files/Statusreport_reviewmethodologycombined.pdf. Accessed 28 July 2020
Chand R (2017) Report on doubling farmers' income, rationale, strategy, prospects and action plan, Government of India, New Delhi. https://niti.gov.in/writereaddata/files/document_publication/DOUBLING%20FARMERS%20INCOME.pdf. Accessed 22 July 2020
Chatterjee R, Purohit RR (2009) Estimation of replenishable groundwater resources of India and their status of utilization. Curr Sci 96(12):1581–1591
FAO (2015) FAOSTAT Database (Rome: Food and Agriculture Organization) (faostat.fao.org)
FAO (2020) Chapter 3: crop water needs, http://www.fao.org/3/s2022e/s2022e07.htm. Accessed 15 July 2020
Foster A, Sekhri S (2008) Can expansion of markets for groundwater decelerate the depletion of groundwater resource in rural India?. https://www.semanticscholar.org/paper/Can-Expansion-of-Markets-for-Groundwater-Decelerate-Foster-Sekhri/1c42efd82dd0162eb2e6c8728844c2d2649102dd. Accessed 28 July 2020
Gandhi VP, Namboodiri NV (2009) Groundwater irrigation in India: gains, costs, and risks. Indian Institute of Management, Ahmedabad
Government of India (2014) Agricultural Statistics at a Glance (New Delhi: Ministry of Agriculture). http://eands.dacnet.nic.in/PDF/Agricultural-Statistics-At-Glance2014.pdf. Accessed 3 Apr 2021
Ground Water Department, Geohydrological Division, Uttar Pradesh (1999) Report on estimation of groundwater resources as per methodology-1997 in district Moradabad. Bareilly, T.M.No. 295/98-99
Ground Water Estimation Committee (GEC), (1997) Ground Water Estimation Methodology—1997, Ministry of Water Resources, Govt of India
GEC-Groundwater Resource Estimation Committee (2009) Ground water resource estimation methodology. Ministry of Water Resources Report. Government of India, Delhi
Gulati A, Meinzen-Dick R, Raju KV (2005) Institutional reforms in Indian irrigation. International Food Policy Research Institute- Sage Publications, New Delhi, p 322
Hassan, G.Z. and Bhutta, M.N. (1996) A water balance model to estimate ground water recharge in the Rechana doab, Pakistan. Irrigation and Drainage Systems. 10(4): 279–317. http://www.indiaenvironmentportal.org.in/files/Statusreport_reviewmethodologycombined.pdf. Accessed 23 Oct 2018
Inocencio, A., & McCornick, P. G. (2008) Economic performance of public investments in irrigation in India in the last three decades. Strategic Analyses of the National River Linking Project (NRLP) of India Series 2, pp 139
Kondepati R (2011) Agricultural groundwater management in Andhra Pradesh, India: a focus on free electricity and its reform. Int J Water Resour Dev 27(2):375–386
Kumar B, Nachiappan RP (1995) A mathematical approach based on tritium tagging technique to evaluate recharge to ground water due to monsoon rains. In: Proceedings of the international symposium on tracer technologies for hydrological systems, Colorado, USA, July, 1995, IAHS, vol 229, pp 237–248
Kumar CP, Seethapathi PV (2002) Assessment of natural groundwater recharge in upper Ganga canal command area. J Appl Hydrol Assoc Hydrol India XV 4:13–20
Lee CH (1915) The determination of safe yield of underground reservoirs of the closed-basin type. Trans Am Soc Civ Eng 78:148–151
Liu Y, Zhang C (1993) A comparative study of calculation methods for recharge of rainfall seepage to ground water in plain area. Ground Water 31(1):12–18
Meinzen-Dick R, Rosegrant M (2005) Chapter 10: emerging water issues in South Asia. In: Babu SC, Gulati A (eds) Economic reforms and food security. Haworth Press Inc., New York, pp 213–229
Murgai R (2001) The green revolution and the productivity paradox: evidence from the Indian Punjab. Agric Econ 25:199–209
Neto AJC, Rodrigues LN (2020) Evaluation of groundwater recharge estimation methods in a watershed in the Brazilian Savannah. Environ Earth Sci 79(6):1–14
Pradhan S (2015) Groundwater studies in lower part of Ganga-Ramganga interbasin using co-active neuro fuzzy inference system and fuzzy logic. http://krishikosh.egranth.ac.in/handle/1/5810072678. Accessed 2 Nov 2018
Pradhan S, Kumar S, Kumar Y, Sharma HC (2019) Assessment of groundwater utilization status and prediction of water table depth using different heuristic models in an Indian interbasin. Soft Comput 23:10261–10285. https://doi.org/10.1007/s00500-018-3580-4
Qian XX, Zhu XY (1987) Determination of rainfall seepage recharge capacity in evaluating ground water resources. Researches on theory-method of ground water resource evaluation. Geological Publishing House, Beijing, pp 120–129
Rodell M, Velicogna I, Famiglietti JS (2009) Satellite-based estimates of groundwater depletion in India. Nature 460:999–1002
Roy AD, Shah T (2002) Socio-ecology of groundwater irrigation in India. In: Intensive use of groundwater challenges and opportunities, pp 307–335
Rushton KR, Redshaw SC (1979) Seepage and groundwater flow. Wiley, Chichester
Sarkar R, Kumar S, Kumar Y, Sharma HC (2007) Comparative performance of Artificial Neural Network and statistical approach in groundwater modelling for Ramganga Bahgul interbasin. J Appl Hydrol XX(4):71–82
Shah T, Scott C, Kishore A, Sharma A (2003) Energy–irrigation nexus in South Asia: approaches to agrarian prosperity with viable power industry (Research Report No. 70). International Water Management Institute, Colombo
Sharma BR, Gulati A, Mohan G, Manchanda S, Ray I, Amarasinghe U (2018) Water productivity mapping of major Indian crops. https://www.thinkasia.org/bitstream/handle/11540/8480/Water_Productivity_Mapping_of_Major_Indian_Crops.pdf?sequence=1. Accessed 15 July 2020
Singh R (2000) Environmental consequences of agricultural development: A case study from the Green Revolution state of Haryana, India. Agric Ecosyst Environ 82:97–103
Takshi KS, Chopra RPS (2004) Monitoring and assessment of groundwater resources in Punjab state. In: Workshop paper on groundwater use in North-West India. Centre for Advancement of Sustainable Agriculture, New Delhi, pp 8–15
Theis CV (1940) The source of water derived from wells—essential factors controlling the response of an aquifer to development. Civ Eng Mag 10(5):277–280
United Nations Environment Program (UNEP) (2008) Reforming energy subsidies: Opportunities to contribute to the climate change agenda. Author, Washington, DC
Wadia DN (1961) Geology of India. Macmillan, London, p 390
Walker D, Parkin G, Schmitter P, Gowing J, Tilahun SA, Haile AT, Yimam AY (2019) Insights from a multi-method recharge estimation comparison study. Groundwater 57(2):245–258
World Bank (2004) Implementation completion report SCL-44410 PPFB-P3340 on a loan in the amount of US$210 million to the Government of India for Andhra Pradesh power sector restructuring project APL I (Report 27775). Author, Washington, DC
World Bank (2010) Sustainable groundwater irrigation: approaches to reconciling demand with resources. Strategic overview series report number 4
Acknowledgements
The authors would like to thank Govind Ballabh Pant University of Agriculture and Technology, Pantnagar, India, for providing an excellent platform for research. Fellowship during the research period to the first author from the Indian Council of Agricultural Research (ICAR), India, is also gratefully acknowledged.
Funding
None.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The author(s) declare that they have no competing interests.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Pradhan, S., Kumar, S., Kumar, Y. et al. Implication of intensive agriculture on groundwater utilization in Ganga-Ramganga interbasin, India. Environ Earth Sci 80, 342 (2021). https://doi.org/10.1007/s12665-021-09602-w
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12665-021-09602-w