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Explore the impact of salinity on river water downstream in regions like Egypt and Pakistan. Learn how irrigation projects contribute to soil salinity and discover solutions to manage salinity levels effectively.
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RiverSaltA spreadsheet program Water and salt balances along rivers in (semi)arid zones that provide water for irrigation and receive drainage return flow
River salinity increases to harmful levels downstream • In irrigation projects along the river the salt concentration of the water increases due to evaporation • The flow of drainage water returned to the river is also more saline and spoils the quality of the river water • Further downstream the soils may become too saline and agriculture suffers.
Downstream river salinity in Egypt and Pakistan • Egypt has a long and big river: the Nile. Its waters are used for extensive irrigation. Downstream, in the North of the Nile Delta, the irrigation water is salty and agricultural lands are barren due to soil salinity. • Pakistan also has a long and big river: the Indus. Downstream, in Sindh province, the irrigation water is salty and many lands are barren due to soil salinity • In Egypt the available amount of irrigation water per ha is more than in Pakistan. • Therefore in Pakistan the problem is more serious than in Egypt
Example of salt import in irrigation project • Good quality water 0.5 g salt / l water • EC = 0.75 dS/m • Irrigation 10 000 m3 per ha per year • Salt import is 5000 kg per ha per year • When salinity is 1 g/l and irrigation is 20000 m3 (sugar cane) then import is 20 T
Example of soil and return flow salinity • If irrigation efficiency is 90% (very high), then 10% of the irrigation water is drained an returned to the river. • If salinity irrigation water is 1 dS/m (reasonable quality) and leaching efficiency is 100%, then soil salinity is 10 dS/m (saline soil) and salinity of return flow is also 10 dS/m • If leaching efficiency is 50%, then soil salinity is 20 dS/m (very saline).
Schematic diagram of river with irrigation projects, return flow, and salinity
Application to reality • The previous diagram has been used in the spreadsheet program SaltyRiver. This will be shown later. • Adaptations of the spreadsheet to local situations can be made without much difficulty • This gives a tool for: • monitoring river and soil salinity • simulate the effects of different measures for salinity control • predict the effects of new developments • For more accuracy one can use the agro-hydro-salinity model SaltMod in each irrigation project separately to determine soil and drainage salinity more precisely
Soil salinity control • In Egypt and Pakistan outfall drains are used to take the salty river water to the sea instead of returning it to the river • In Australia and USA evaporation ponds (artificial lakes) are used so that drainage water is evaporated instead of returning it to the sea • In India land is sacrificed (also called retired): part of the agricultural land is taken out of use or put under salt tolerant trees and allowed to become saline. Evaporation occurs by capillary rise. • For Garmsar I proposed a combined system of drainage and strip cropping
Conclusions • The optimal management of river water, irrigation, drainage for salinity control consists of a combination of measures adjusted to local conditions • The interactions are complex • It is useful to apply simulation models as a tool to assist the managers to reach the optimal decisions. • Now we will demonstrate the SaltyRiver program