CIVE 633 - ENVIRONMENTAL HYDROLOGY
SUSTAINABILITY OF IRRIGATED AGRICULTURE

Irrigated agriculture has been practiced for more than 10000 years.
Productivity from irrigated lands tends to be higher than rainfed (dryland) agriculture.
In the U.S. 25% of all crops originates in 10% of the land.
Irrigation in arid or semiarid regions always degrades water quality downstream.
Without proper management, the land becomes waterlogged and salinized.
Drainage waters from irrigated lands carry salt that requires disposal.
Can irrigation be sustained indefinitely?

A LOOK BACK

The Egyptians depended on irrigation for 3000 years.
In the Indus basin there are drainage problems.
Can these problems be solved?
Salton Sea developed by dumping agricultural wastewaters in a closed basin.
Salinity and sodicity have plagued the development of the San Joaquin valley from the beginning.
Discovery of selenium in the biota which fed on Kesterton reservoir has led to renewed evaluation of the disposal of agricultural drainage.
Selenium originated in the geology and accumulated in the reservoir.
All irrigation enterprises face problems of salinity management.
All must consider the safe disposal of wastewater.

SALINITY AND OTHER CONTAMINANTS

Salinity problems have been recognized for a long time.
Ignoring salinity in irrigation planning is often due to politics rather than to technical understanding.
Many engineers have devoted their careers to salinity management.
It has long been recognized that salinity management requires removing excess salts from the root zone, i.e., drainage.
High concentrations of selenium, molybdenum, arsenic, and boron were found in Kesterton.
These minerals originate in the soil or rocks; they are mobilized by irrigation and then displaced with irrigation drainage.
Conditions similar to Kesterton are likely to be found elsewhere.
Knowledge of local and regional geochemistry becomes paramount to the long-term success of a project.
Items of concern include not only salts but also trace elements, excessive quantities of nutrients such as nitrate, and pesticides.
Managing irrigation wastewaters has become difficult and controversial.

AN ASSESSMENT

Irrigation in semiarid regions must have drainage.
A downward flux of water must move through the soil profile to prevent the concentration of solutes in the soil from rising to a level that cannot be tolerated by crops.
In some instances, the natural drainage rate is sufficient to meet this need.
In other instances, engineered drainage systems are required.
Recognition of the need for drainage varies from place to place, depending on the local geohydrology.
The concepts of leaching fraction and leaching requirement have been developed to manage salts.
Salts must be removed from the system to maintain an acceptable (maximum) concentration of solutes in the root zone.
In most natural systems, upland drainage finds its way into rivers and then into oceans.
True meaning of rivers: to carry excess salts and transported sediments to the sea.
Irrigation tends to accelerate salt displacement.
EPA estimated that 1/3 of the salt in the Colorado river can be attributed to irrigation.
This is due to new salt (byproduct of the functioning of the biosphere), but also to old salt (fossil salt) that was mobilized by irrigation.
Closed basins accumulate salt.
Absolute lack of drainage leads to changes; these are biological (more salinity eliminates fish but invertebrate species may survive) and of type of usage (Salton vs. Salt Lake in Utah).
All irrigation ultimately degrades water quality offsite for some uses.
A permanent irrigation agriculture (benefit) requires the sacrifice of some value elsewhere (loss).
Strategies

There are ways to minimize the effects of irrigation on downstream salinity.
Limiting the leaching fraction to the amount needed to maintain full growth.
Salt comes with water (imported), is already there in the profile (old), and is created by the mere process of crop production (new).
All salts need to be removed.
Alternative irrigation technologies may minimize but do not eliminate the need for drainage.
Desalination is technically possible, but prohibitively expensive.
Damage from toxic substances (trace elements) can be more costly than damage from salts.
Efficient management of fertilizers and pesticides reduces losses into drainage water.
Saline seeps reflect the movement of salt downstream toward the ocean; they reflect geologic changes from closed drainage to open drainage (due to tectonism).
Management of saline seeps is technologicaly cumbersome and expensive.

COMPARING THE OPTIONS

It may be assumed that the use of land for irrigated agriculture is the preferred choice.
Successful irrigation depends on adequate drainage, which implies some offsite loss which tends to counteract the irrigation benefit.
Harnessing water for irrigation takes it from other uses (its natural use, which is to transport the salt to the ocean).
Irrigation always carries an opportunity cost.
Who pays for this cost? Issue is not resolved. Example: Salton Sea.
Wetlands in California have been reduced to less than 10% of the original area.
Given the objective of maintaining irrigated agriculture, there is a cost (additional drainage) which somebody has to pay for.
Bureau of Reclamation was created in 1902 to "reclaim" western lands.
Reclaim means irrigate; irrigate means degrade downstream water quality.
Benefits of irrigation have been allocated (short term); losses have not been paid (long term).
It can no longer be taken for granted that irrigated agriculture should be subsidized and protected.
Societal values have changed from 1970 to 2000.
There are issues of water rights vs conservation re: Imperial irrigation is being forced to conserve water in view of their usage of water amounts much in excess of their allocated rights.
Some of that water will be saved by lining the All-American Canal, resulting in losses to Mexican agriculture.
Some of that water will be sold to San Diego.
Salton Sea lost, but gained a few millions recently (300?) to "restore."
Society no longer considers irrigation to be the preferred use.
Should irrigation (and crop production) be transferred overseas, where it is cheaper (and not regulated?)
Developed societies such as the U.S. will eventually replace natural services for artificial services.
Stability of human-generated systems remains an issue.
Political forces drive the system because the issues are matters of policy.
Political decisions are influenced by the facts and how they are perceived (which is not the same).
Costs and benefits of alternative options should be identified.
Holistic, interdisciplinary analysis is a must.
In many cases, lack of data implies a risk or uncertainty.

CONCLUSIONS

Little question exists that irrigation in semiarid climates can be sustained indefinitely (Yes or No?)
Salinization can be avoided by providing adequate drainage.
Drainage exacts a price.
Drainage water degrades the quality of water along its disposal route.
Open drainage, closed drainage, and toxic drainage all exact a prize.
Irrigated agriculture must adapt to changing physical and societal conditions to survive.
Irrigated agriculture may flourish under the proper circumstances.
Reduced subsidies (pay actual cost!) may be the only way to weed out inefficient operations.
Problems of irrigation wastewater, salinity, and contamination are of global reach.

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