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Old 04-14-2011, 04:51 PM   #1
outlook064
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Default Office Standard Managing Saline Soils.html

Print this truth sheet no. 0.503 Managing Saline Soils by G.E. Cardon, J.G. Davis, T.A. Bauder, and R.M. Waskom1 (5/07) Quick Details... An believed 980,000 acres of irrigated land in Colorado are impacted by salts. Crop losses may happen with irrigation water containing as tiny as 700 to 850 mg/L TDS (whole dissolved solids) or EC>1.2 dS/m. Salt-affected soils could inhibit seed germination, retard plant growth, and cause irrigation difficulties. Saline soils cannot be reclaimed by chemical amendments, conditioners or fertilizers. Saline soils are often reclaimed by leaching salts from the plant root zone. Soils high in salt and/or sodium could limit crop yields. Salt-affected soils may contain an excess of water-soluble salts (saline soils), exchangeable sodium (sodic soils) or both an excess of salts and exchangeable sodium (saline-sodic soils). Periodic soil testing and treatment, combined with proper management procedures, can improve the conditions in salt-affected soils that contribute to poor plant growth.
Salinity problems are caused from the accumulation of soluble salts in the root zone. These excess salts reduce plant growth and vigor by altering h2o uptake and causing ion-specific toxicities or imbalances. Establishing good drainage is generally the cure for these problems, but salinity problems are often more complex. Proper management procedures, combined with periodic soil tests, are needed to prolong the productivity of salt-affected soils.

This simple fact sheet describes techniques for managing saline soils. Management for sodic soils might differ and is described in simple fact sheet 0.504, Managing Sodic Soils. You also may possibly want to review simple fact sheet 0.521, Diagnosing Saline and Sodic Soil Problems to determine if you have a saline soil, sodic soil or perhaps another problem in your field.
Salt Sources
Saline soils are found throughout Colorado. These salts originate from the natural weathering of minerals or from fossil salt deposits left from ancient sea beds. Salts accumulate in the soil of arid climates as irrigation water or groundwater seepage evaporates, leaving minerals behind. Irrigation water often contains salts picked up as h2o moves across the landscape, or the salts may possibly come from human-induced sources such as municipal runoff or drinking water treatment. As drinking water is diverted in a basin, salt levels increase as the water is consumed by transpiration or evaporation.
Table 1. Common salt compounds. Salts are ionic crystalline compounds consisting of a cation and an anion. Salt compound Cation (+) Anion (-) Common name NaCl sodium chloride halite (table salt) Na2SO4 sodium sulfate Glauber’s salt MgSO4 magnesium sulfate epsom salts NaHCO3 sodium bicarbonate baking soda Na2CO3 sodium carbonate sal soda CaSO4 calcium sulfate gypsum CaCO3 calcium carbonate calcite (lime) Measuring Soil Salinity
Saline soils contain large amounts of drinking water soluble salts that inhibit seed germination and plant growth. The salts are white, chemically neutral, and include chlorides, sulfates, carbonates and sometimes nitrates of calcium,Office Standard, magnesium, sodium and potassium (Table 1).

Salinity is measured by passing an electrical current through a soil solution extracted from a saturated soil sample. The ability of the solution to carry a current is called electrical conductivity (EC). EC is measured in deciSiemens per meter (dS/m), which is the numerical equivalent to the old measure of millimhos per centimeter (Table 2). The lower the salt content of the soil, the lower the dS/m rating and the less the effect on plant growth.

Yields of most crops are not significantly impacted where salt levels are 0 to 2 dS/m. Generally, a level of 2 to 4 dS/m affects some crops. Levels of 4 to 5 dS/m affect many crops and above 8 dS/m affect all but the very tolerant crops (Table 4).
Table 2. Terms, units and conversions. Symbol Meaning Units Complete Salinity TDS Total dissolved solids mg/La; ppmb EC Electrical conductivity
dS/mc; mmho/cmd; µmho/cme Conversions 1 dS/m = 1 mmho/cm = 1000 µmho/cm 1 mg/L = 1 ppm amg/L = milligrams per liter; bppm = parts per million; cdS/m = deciSiemens per meter at 25° C;
dmmho/cm = millimhos per centimeter at 25° C; eµmho/cm = micromhos per centimeter at 25°C Treatment of Saline Soil
Saline soils cannot be reclaimed by chemical amendments, conditioners or fertilizers. A field can only be reclaimed by removing salts from the plant root zone. In some cases, selecting salt-tolerant crops might be needed in addition to managing soils.

There are three ways to manage saline soils. First, salts can be moved below the root zone by applying more drinking water than the plant needs. This method is called the leaching requirement method. The second method, where soil moisture conditions dictate, combines the leaching requirement method with artificial drainage. Third, salts can be moved away from the root zone to locations in the soil, other than below the root zone, where they are not harmful. This third method is called managed accumulation.
Leaching Requirement
For most surface irrigation systems in Colorado (furrow and flood), irrigation inefficiency (or over-irrigation) generally is adequate to satisfy the leaching requirement. However, poor irrigation uniformity often results in salt accumulation in parts of a field or bed. Surface irrigators should compare leaching requirement values to measurements of irrigation efficiency to determine if additional irrigation is needed. Adding more water to satisfy a leaching requirement reduces irrigation efficiency and may possibly result in the loss of nutrients or pesticides and further dissolution of salts from the soil profile.

Leaching is accomplished on a limited basis at key times during the growing season, particularly when a grower might have high quality drinking water available. Surface water in most areas of the state tend to have lower salinity than shallow, alluvial groundwater. Deep groundwater might have an even lower salinity than either shallow groundwater or surface h2o. In situations where a grower has multiple h2o sources of varying quality, consider planned leaching events at key salinity stress periods for a given crop.


Most crops are highly sensitive to salinity stress in the germination and seedling stages. Once the crop growns past these stages, it can often tolerate and grow well in higher salinity conditions. Planned periodic leaching events might include a post-harvest irrigation to push salts below the root zone to prepare the soil (especially the seedbed/surface zone) for the following spring. Fall is the best time for a large, planned leaching event because nutrients have been drawn down. However, since each case is site-specific, examine the condition of the soil, groundwater, drainage, and irrigation system for a given field before developing a sound leaching plan.
Leaching Plus Artificial Drainage
Where shallow h2o tables limit the use of leaching, artificial drainage may be needed. Cut drainage ditches in fields below the water table level to channel away drainage water and allow the salts to leach out. Drainage tile or plastic drainpipe can also be buried in fields for this purpose. Proper design and construction of a drainage system is critical and should be performed by a trained professional, such as your local USDA-Natural Resources Conservation Service (NRCS).

With all artificial drainage systems you must also consider disposal of the drainage water. Restrictions on the discharge of drain water to streams may apply in certain situations and should be investigated through the Colorado Department of Public Health and Environment. In the case of regulated discharge, treatment or collection and evaporation of the water on site might be required and could add significant costs.

The advantage of artificial drainage is that it provides the ability to use high quality, low salinity irrigation drinking water (if available to a grower) to completely remove salts from the soil. However, artificial drainage systems will not work where there is no saturated condition in the soil. H2o will not collect in a drain if the soil around it is not saturated.
Table 3. Approximated drinking water application needed to leach salts. Example: If a soil’s electrical conductivity is 8 mmhos/cm,Office Pro 2010 Key, and you want to reduce it to 4 mmhos/cm. This represents a 50 percent reduction in salts. Therefore, 6 inches of h2o would be required.
After drainage appears adequate, the leaching process can begin. Table 3 shows how much drinking water is required to leach salts. Actual salt reduction depends upon drinking water quality, soil texture and drainage.
Figure 1. Salt management in double-row bed system. Figure 2. Salt management in single-row bed systems. Managed Accumulation
In addition to leaching salt below the root zone, salts can also be moved to areas away from the primary root zone with certain crop bedding and surface irrigation systems. Figures 1 and 2 illustrate several ways to manage salt accumulation in this manner. The goal is to ensure the zones of salt accumulation stay away from germinating seeds and plant roots. Irrigation uniformity is essential with this method. Without uniform distribution of h2o, salts will build up in areas where the germinating seeds and seedling plants will experience growth reduction and possibly death.

Double-row bed systems require uniform wetting toward the middle of the bed. This leaves the sides and shoulders of the bed relatively free from injurious levels of salinity. Without uniform applications of h2o (one furrow receiving more or less than another), salts accumulate closer to one side of the bed. Periodic leaching of salts down from the soil surface and below the root zone may still be required to ensure the beds are not eventually salted out.

Alternate furrow irrigation might be desired for single-row bed systems. This is accomplished by irrigating every other furrow and leaving alternating furrows dry. Salts are pushed across the bed from the irrigated side of the furrow to the dry side. Care is needed to ensure enough water is applied to wet all the way across the bed to prevent build up in the planted area. This method of salinity management can still result in plant injury if large amounts of natural rainfall fill the normally dry furrows and push salts back across the bed toward the plants. This phenomenon also occurs if the normally dry furrows are accidentally irrigated.
Sprinkler Irrigation
Sprinkler-irrigated fields with poor drinking water quality present a challenge because it is difficult to apply enough h2o to leach the salts and you cannot effectively utilize row or bed configurations to manage accumulation. Growers should monitor the soil EC and irrigation h2o salinity. Where adequate irrigation water exists above crop requirements, a leaching fraction (or percent of additional water needed above crop requirements) can be calculated for sprinkler irrigated fields using this equation:

In this equation, EC max is the maximum soil EC wanted in the root zone. (See Table 4.)
Apply this leaching fraction to coincide with periods of low soil N and residual pesticide. Again, fall is an optimal time to move salts below the root zone.
Table 4. Potential yield reduction from saline soils for selected crops. Field crops Barley Sugarbeets* Wheat Sorghum Soybean Corn Bean Forages Tall wheatgrass Wheatgrass Crested wheatgrass Tall fescue Orchardgrass Alfalfa Meadow foxtail Cloveralsike, red, ladino, strawberry Bluegrass and other turf ** Vegetables Broccoli Cucumber Cantaloupe Spinach Cabbage Potato Sweet corn Lettuce Onion Carrot *Sensitive during germination and emergence, ECe should not exceed 3dS/m at this time.
Excerpted from R. S. Ayers and D.W. Westcot, 1976, Water Quality for Agriculture, Irrigation and Drainage Paper 29, FAO, Rome. Crop salt tolerance data in the table were developed, almost entirely, by the U.S. Salinity Laboratory, Riverside, CA.
**For specifics on turfgrass species, see Colorado State University Extension fact sheet 7.227, Growing Turf on Salt-Affected Sites. Crop Tolerance to Soil Salinity
Excessive soil salinity reduces the yield of many crops. This ranges from a slight crop loss to complete crop failure, depending on the type of crop and the severity of the salinity problem.

Although several treatments and management practices can reduce salt levels in the soil, there are some situations where it is either impossible or too costly to attain desirably low soil salinity levels. In some cases, the only viable management option is to plant salt-tolerant crops. Sensitive crops, such as pinto beans, cannot be managed profitably in saline soils. Table 4 shows the relative salt tolerance of field, forage, and vegetable crops. The table shows the approximate soil salt content (expressed as the electrical conductivity of a saturated paste extract (ECe) in dS/m at 25 degrees C) where 0,Office 2010 Professional Plus, 10, 25, and 50 percent yield decreases might be expected. Actual yield reductions will vary depending upon the crop variety and the climatic conditions during the growing season.

Fruit crops might show greater yield variation because a large number of rootstocks and varieties are available. Also, stage of plant growth has a bearing on salt tolerance. Plants are usually most sensitive to salt during the emergence and early seedling stages. Tolerance usually increases as the crop develops.

The salt tolerance values apply only from the late seedling stage through maturity, during the period of most rapid plant growth. Crops in each class are generally ranked in order of decreasing salt tolerance.
Other Management Options Residue Management
Crop residue at the soil surface reduces evaporative water losses, thereby limiting the upward movement of salt (from shallow, saline groundwater) into the root zone. Evaporation and thus, salt accumulation, tends to be greater in bare soils. Fields need to have 30 percent to 50 percent residue cover to significantly reduce evaporation. Under crop residue, soils remain wetter, allowing fall or winter precipitation to be more effective in leaching salts, particularly from the surface soil layers where damage to crop seedlings is most likely to take place.

Plastic mulches used with drip irrigation effectivly reduce salt concentration from evaporation. Sub-surface drip irrigation pushes salts to the edge of the soil wetting front, reducing harmful effects on seedlings and plant roots.
Pre-plant Irrigation
As mentioned before, most crop plants are more susceptible to salt injury during germination or in the early seedling stages. An early-season application of good quality water, designed to fill the root zone and leach salts from the upper 6 to 12 inches of soil, may possibly provide good enough conditions for the crop to grow through its most injury-prone stages
Irrigation Frequency Management
Salts are most efficiently leached from the soil profile under higher frequency irrigation (shorter irrigation intervals). Keeping soil moisture levels higher between irrigation events effectively dilutes salt concentrations in the root zone, thereby reducing the salinity hazard.

Most surface irrigation systems (flood or furrow systems) cannot be controlled to apply less than 3 or 4 inches of water per application and are not generally suited to this method of salinity control. Sprinkler systems,Microsoft Office 2007 Pro Plus, particularly center-pivot and linear-move systems configured with low energy precision application (LEPA) nozzle packages or properly spaced drop nozzles, and drip irrigation systems provide the best control to allow this type of salinity management.
Summary Under irrigated conditions in arid and semi-arid climates, the build-up of salinity in soils is inevitable. The severity and rapidity of build-up depends on a number of interacting factors such as the amount of dissolved salt in the irrigation h2o and the local climate. However, with proper management of soil moisture, irrigation system uniformity and efficiency, local drainage, and the right choice of crops, soil salinity can be managed to prolong field productivity.

1 G.E. Cardon, associate professor, soil and crop sciences; J. Davis, Colorado State University Extension soils specialist and professor,Windows 7 X86, soil and crop sciences; T.A. Bauder, Extension water quality specialist; and R.M. Waskom, Extension h2o resource specialist. 7/03. Reviewed 5/07.

Colorado State University, U.S. Department of Agriculture and Colorado counties cooperating. Extension programs are available to all without discrimination. No endorsement of products mentioned is intended nor is criticism implied of products not mentioned.

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Updated Wednesday, Could 12, 2010
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