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7.9: Salinity and the Environment

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    Irrigation always degrades water quality and can cause a salinity hazard. Without proper management, the land can become waterlogged and salinized. Regardless of management, drainage water from irrigated lands carries salt that requires disposal. Questions arise as to whether salination is inevitable and if the environment is jeopardized.

    Where salinity is a hazard, irrigation must have drainage. A net downward movement must occur through the soil profile to prevent the accumulation of soluble salts to a level detrimental to crops. Whether drainage is natural or man-made, the rate of movement of soil water must be sufficient to prevent salination. This drainage water must go somewhere. Depending on the geologic and hydrologic conditions, the need for drainage may become evident after only a few irrigations or after many decades.

    Permanent irrigated agriculture frequently requires the sacrifice of some value elsewhere. An example is the Colorado River in the southwest corner of the United States. Lohman et.al. (1988) estimated damages from salinity for the period of 1976 to 1985 to be $311 million per year when based on a reference salinity of 500 mg/L, the Public Health Service standard for drinking water. Damages occurred to agriculture, households, water utilities, and industry. Of the figure quoted, $113 million reflect damages to agriculture.

    Ultimately, saline drainage water must be transported out of the region, disposed of locally, or treated. It is technically feasible to treat saline water. Several desalination studies have evaluated reverse osmosis. The world’s largest desalination plant was constructed near Yuma, Arizona, to remove salt from irrigation drainage water before it returns to the Colorado River. However, it’s difficult to justify such an approach economically (van Schilfgaarde, 1982). An alternative to treating the water is to convey it to evaporation ponds. Experience in California indicates that 10 to 14% of the land area must be devoted to evaporation ponds. Loss of land, construction costs, and avoidance of leakage makes this alternative unattractive. Transporting saline water out of the region remains the primary means of disposal using natural or manmade water courses.

    7.9: Salinity and the Environment is shared under a CC BY-NC-ND 4.0 license and was authored, remixed, and/or curated by LibreTexts.