Your search found 3 records
1 Amarasinghe, Upali A.; Sikka, Alok; Mandave, Vidya; Panda, R. K.; Gorantiwar, S.; Chandrasekharan, Kiran; Ambast, S. K. 2021. A re-look at canal irrigation system performance: a pilot study of the Sina Irrigation System in Maharashtra, India. Water Policy, 23(1):114-129. [doi: https://doi.org/10.2166/wp.2020.291]
Irrigation systems ; Irrigation canals ; Water use efficiency ; Water productivity ; Performance evaluation ; Water scarcity ; Water supply ; Groundwater irrigation ; Water potential ; Reservoir storage ; Cropping patterns ; Irrigated sites ; Land use ; Estimation ; Satellite observation ; Economic aspects / India / Maharashtra / Sina Irrigation System
(Location: IWMI HQ Call no: e-copy only Record No: H050175)
(0.48 MB)
The general perception of canal irrigation systems in India is one of built infrastructure with low service performance. This paper presents an analytical framework, applied to the Sina medium irrigation system in Maharashtra state of India, to study the performance of an expanded water influence zone (WIZ) including a buffer zone outside the canal command area (CCA) influenced by the irrigation system’s water resources. The framework used satellite-based estimates of land-use and cropping patterns. The results indicate that there is hardly any gap between the irrigation potential created (IPC) and the irrigation potential utilized (IPU) in the CCA. The fraction of consumptive water use (CWU) of irrigation is low in the CCA, but almost one in the WIZ, due to the reuse of return flows in the WIZ. Future investments should focus on increasing economic water productivity ($/m3 ) in order to enhance the resilience of the farming community in the WIZ, which is frequently affected by water scarcity.
2 Amarasinghe, Upali A.; Sikka, Alok; Mandave, Vidya; Panda, R. K.; Gorantiwar, S.; Ambast, S. K. 2021. Improving economic water productivity to enhance resilience in canal irrigation systems: a pilot study of the Sina Irrigation System in Maharashtra, India. Water Policy, 23(2):447-465. [doi: https://doi.org/10.2166/wp.2021.231]
Water productivity ; Economic analysis ; Irrigation systems ; Canals ; Resilience ; Cropping patterns ; Water allocation ; Groundwater irrigation ; Groundwater recharge ; Water costs ; Benefit-cost ratio ; Water use ; Drought tolerance ; Water scarcity ; Rain ; Monsoons ; Reservoir storage / India / Maharashtra / Sina Irrigation System
(Location: IWMI HQ Call no: e-copy only Record No: H050317)
https://iwaponline.com/wp/article-pdf/23/2/447/879066/023020447.pdf
https://vlibrary.iwmi.org/pdf/H050317.pdf
https://vlibrary.iwmi.org/pdf/H050317.pdf
(0.40 MB) (411 KB)
This paper proposes scenarios to achieve more crop per drop and irrigation for all in water-scarce irrigation systems, with a particular reference to India. It uses economic water productivity (EWP) and water cost curve for EWP as tools to reallocate irrigation consumptive water use (CWU) and identify economically viable cropping patterns. Assessed in the water-scarce Sina irrigation system in Maharashtra, India, the method shows that drought-tolerant annual crops such as fruits and/or fodder should be the preferred option in irrigated cropping patterns. Cropping patterns with orchard or fodder as permanent fixtures will provide sustainable income in low rainfall years. Orchards in combination with other crops will increase EWP and value of output in moderate to good rainfall years. Governments should create an enabling environment for conjunctive water use and allocation of CWU to achieve a gradual shift to high-value annual/perennial crops as permanent fixtures in cropping patterns.
3 Amarasinghe, Upali A.; Amarnath, Giriraj; Alahacoon, Niranga; Aheeyar, Mohamed; Chandrasekharan, Kiran; Ghosh, Surajit; Nakada, Toru. 2021. Adaptation to climate variability in Sri Lanka: a case study of the Huruluwewa Irrigation System in the Dry Zone. Colombo, Sri Lanka: International Water Management Institute (IWMI). 30p. (IWMI Working Paper 200) [doi: https://doi.org/10.5337/2021.229]
Climate variability ; Climate change adaptation ; Irrigation systems ; Arid zones ; Tank irrigation ; Irrigation canals ; Irrigation management ; Land use ; Cropping patterns ; Water supply ; Water depletion ; Crop production ; Water use efficiency ; Irrigation efficiency ; Water productivity ; Water availability ; Drought ; Rainfall patterns ; Risk ; Resilience ; Water scarcity ; Water management ; Reservoirs ; Water spreading ; Catchment areas ; Water storage ; Groundwater recharge ; Water accounting ; Water policies ; Seasonal cropping ; Diversification ; Crop water use ; Consumptive use ; Farmers ; Farm income ; Remote sensing ; Geographical information systems ; Case studies / Sri Lanka / India / North Central Province / Huruluwewa Irrigation System / Sina Irrigation System
(Location: IWMI HQ Call no: IWMI Record No: H050737)
(7.75 MB)
This paper assesses how the Huruluwewa tank (HWT) irrigation system in the North Central Province of Sri Lanka adapts to climate variability. The lessons learned in the HWT will be helpful for many water-scarce irrigation systems in the country, which bear high climate risks. Recurrent droughts are the bane of agriculture in the Dry Zone, comprising three-fourths of the land area spread over the Northern, North Central and Eastern provinces. In the HWT, the fifteenth largest canal irrigation system in the country, adaptation to climate variability happens on several fronts: changes made by the irrigation management to the water release regime; changes in the cropping patterns practiced by farmers in the command area; and the use of groundwater, which is recharged from rainfall, reservoir storage and canal irrigation, as supplemental irrigation. Such adaptation measures ensure that the available water supply in the reservoir is adequate for 100% cropping intensity over two cropping seasons, even in drought years, and enhances economic water productivity in terms of value per unit of consumptive water use. Moreover, irrigation management should consider groundwater recharge through canal irrigation as a resource, which brings substantial agricultural and economic benefits not only for the command area but also outside the command area. The adaptation patterns implemented in HWT demonstrate how water-scarce irrigation systems can achieve higher economic water productivity, i.e., generate ‘more income per drop’ to enhance climate resilience for people in and outside the canal command areas.
Powered by DB/Text WebPublisher, from
