Cotton Fertility Management
Extension Professor, Agronomy
The proper fertilization of cotton is difficult to determine because many variables can affect development and production. Anything that causes plant stress will affect nutrient uptake. Some factors involved are: soil texture, drainage, field preparation, weather, variety, time of planting, plant populations, emergence and stand, previous crop, and carry-over fertility and/or chemicals. A current soil test is still the best tool for taking the guesswork out of fertilization, and a balanced fertility program is necessary for good yields.
A cotton fiber consists primarily of cellulose, which is comprised of hydrogen, oxygen and carbon. These elements form the backbone for every molecule and plant part. After ginning, the mineral nutrients of nitrogen (N), phosphorous (P) potassium (K) and micronutrients are removed with the seed and trash and make up only 1% of a bale's weight.
Table 1 gives the nutrient content of a bale (480 pounds lint) of cotton.
Typical nutrient content of cotton (pounds per bale)
|Above ground (leaves, stems, fruit)||Seed cotton||Lint|
|Nitrogen||62||35 to 40||1|
|Phosphate (P2O5)||22||13 to 20||0.3|
|Calcium||27 to 62||1||0.2|
|Magnesium||11 to 27||5||0.3|
|Sulfur||8 to 16||1 to 2||trace|
All other nutrients contribute at most 3 pounds of weight to the leaves, stems and bolls
Cotton Physiology Today, volume 2, no. 3, National Cotton Council, Memphis, Tennessee.
Soil nutrients are taken up in direct proportion to growth and temperature. Total nutrient uptake for nitrogen, phosphorus and potassium tracks cumulative heat units precisely. During the spring growing months when heat units are low, cotton grows slowly and takes only limited amounts of nutrients. It is during the peak growing months of June and July when nutrients need to be most readily available.
Cotton absorbs the highly soluble and less soluble nutrients by different methods. The highly soluble nutrients in the oxidized form of nitrate, sulfate and borate are readily available for plant uptake in the solution of water but can be readily leached from the soil. Mobility in soil solution reduces the value of soil sampling for soluble nutrients (nitrogen, sulfur and boron), but soil sampling is useful at any time of the year for less mobile nutrients (phosphorus, potassium, calcium and magnesium) and soil acidity.
Plants can use two forms of soil nitrogen (N): ammonium (NH4+) and nitrate (NO3-). The NH4+ form is held in the soil by negatively charged soil clays or colloids. Because soils have this negative charge, the NO3- form (also negatively charged) is repelled by soil particles and is subject to movement with water in the soil profile.
Nitrification is a bacterial process in the soil that involves changing the ammonium form of nitrogen to the nitrate form. Conditions that affect the speed of the reaction are: soil oxygen, pH, temperature and moisture. Denitrification (especially under waterlogged soil conditions) occurs when anaerobic bacteria get their oxygen from chemical forms, such as the nitrate molecule. In the process of breaking down the nitrate molecule to obtain oxygen, nitrogen loss occurs when nitrogen gases are released to the atmosphere.
For economic yields, cotton must have the right amount of nitrogen in all phases of growth and fruit development. Excessive nitrogen delays maturity, causes rank growth, can intensify insect infestations, encourages diseases and increases the risk of boll rot and reduced lint quality. A nitrogen deficiency will cause small stalks, pale green leaves, small bolls, fruit shed and low yields.
Very little nitrogen is used by the cotton plant in the seedling stage. The heaviest demand for nitrogen is during the fruiting stages of squaring and boll formation, but the amount of nitrogen required for optimum yields will vary with the situation. Based on studies at the MU Delta Research Center, 80 to 120 pounds of nitrogen per acre is the recommended total N amount for the season in irrigated, continuous cotton on a sandy or silt loam soil having a yield potential of two or more bales per acre. It can be split so that one-third of the total N is pre-plant and the remainder side-dressed at pre-bloom, or the entire 80 to 120 pounds can be side-dressed before bloom. Nonstressed cotton can be side-dressed until about three weeks after first bloom with good results.
In the case of nonirrigated cotton, or where cotton follows soybeans or corn (with a likelihood of residual nitrogen), the nitrogen rate should probably be reduced.
If the side-dress nitrogen is applied prior to early square, the cotton plant may run out of nitrogen too early and possibly reduce the top crop. On the other hand, late applications of nitrogen (especially excess nitrogen) can delay maturity.
Cotton farmers can use stabilizer additives and urea with polymer coatings to improve the efficiency of nitrogen fertilizer. Broadcasting urea fertilizer treated with N-(n-butyl) thiophosphoric triamide (NBPT) reduces volatilization losses from the soil surface compared to regular urea. Controlled release nitrogen fertilizer is blended with urea to prevent losing most of the nitrogen to denitrification and leaching after excessive rainfall. Controlled-release fertilizer is polymer-coated. The danger of applying all of the nitrogen in the controlled release form is that too much could become available late in the season, resulting in delayed boll maturity.
To summarize, plan a fertility program based on past field production levels and realistic expectations. Only small amounts of nitrogen are needed in the seedling stage, and split applications are recommended. Applying controlled-release nitrogen minimizes potential N losses. If the season gets off to a bumper start, there is still time to supplement with extra nitrogen, using soil and plant monitoring. The correct amount of nitrogen will result in an abrupt nitrogen deficiency and fruiting cutout around mid to late August, which helps mature the crop for defoliation and harvest.
Solubility of phosphorus (P) in the soil is the opposite extreme of nitrogen. Phosphorus has low mobility in the soil, and leaching is not a problem. Instead, mobility to the roots is the prime limitation to uptake. Because of the low mobility of phosphorus, root interception is the prime method of uptake, regardless of soil pH. Cotton roots are aided in their interception of soil phosphorus by mycorrhizal fungi. These fungi grow in the small feeder roots and surrounding soil. They derive food from the plant and in return increase uptake of immobile nutrients by enhanced interception. Cotton is highly dependent on mycorrhizae for phosphorus uptake.
Phosphate is tightly bound in the soil, especially at either low or high pH, which reduces its solubility. Cold soils further decrease phosphorus uptake due to the slow root growth and reduced solubility of phosphate in cold water. Despite cotton's peak consumption of phosphorus during the summer months, deficiencies often occur in seedling cotton, when the plant outgrows the stored phosphorus in the seed.
Because of the strong influence of soil temperature on phosphorus uptake, winter crops such as small grains generally require a higher level of soil phosphorus than do warm-season crops, such as cotton. Phosphorus fertilizer is often applied to these rotation crops, so cotton benefits from residual carry-over. A high level of residual phosphorus is present in much of the alluvial soil in the Missouri Bootheel.
Where carry-over phosphorus is not available, such as with continuous cotton, applications are made to provide phosphorus during the "cold soil" periods, often as a starter fertilizer mixed in the surface soil. Subsoils can become deficient in phosphorus due to its poor mobility, which restricts root growth and water uptake from the subsoil.
The Bray I soil test, or weak Bray test, is used to determine available phosphorus. An available phosphorus level of 45 pounds per acre is recommended.
Of all the nutrients, potassium (K) is the only one that comes close to being specific to a plant part. All nutrients (including potassium) are needed during the plant's entire growth cycle, but the need for potassium rises dramatically when bolls are set on the plant. Bolls are major sinks for potassium, and high concentrations of potassium are required to maintain sufficient water pressure for fiber elongation. Potassium is also involved in enzyme activation and pH balance in the cell, which is important for plant health and disease suppression.
Potassium mobility in soils is intermediate between nitrogen and phosphorus but is not easily leached because it has a positive charge (K+), which causes it to be attracted to negatively charged soil colloids. Roots have to grow near the source of potassium, but mycorrhizae are not required for potassium uptake. Potassium is stored in leaves for reuse later by developing bolls, just like nitrogen. Peak need for potassium is during boll filling, and to be available at this time potassium must be in solution where late-season roots are inactive.
When fruit retention is low, crop demand for potassium is less. Foliar potassium has been successfully used in some areas to partially satisfy potassium demand for high-yield conditions, but soil applications should be the best way to supply all fertilizer nutrients, including potassium.
The desired potassium soil test level varies with the yield goal and cation exchange capacity (CEC) of the soil. The desired exchangeable potassium level would be 220 pounds per acre +5 (CEC), so a silt loam soil with a cation exchange capacity of 16 would need a potassium soil test level of 300 pounds per acre to place it in the high range. Additional amounts would serve as a "reserve" supply. Fertilizer potassium often is applied prior to winter tillage to allow mixing and to reduce surface buildup.
Regular soil tests will provide most of the information that is necessary to build an efficient fertilization program. However, a separate boron analysis is needed for certain suspect fields (low organic matter, excess lime, sandy texture, severe fruit drop and/or delayed maturity).
Although a micronutrient, boron (B) plays an essential role in plant cell formation and in converting nitrogen and carbohydrates into protein. It performs a key function in the growth and fruiting process and must not be overlooked. The farther north cotton is produced, the more crucial boron supply becomes. This is due to a shorter season and lower temperatures during the latter part of the fruiting season.
Most fertilizer dealers can add boron with other nutrients in a fertilizer blend. For a 20.5% boron fertilizer, such as Solubor, which is highly soluble in water, broadcast apply about 5 pounds of Solubor for soils with medium boron levels and 10 pounds of Solubor for soils with low boron levels.
Another option is to foliar spray B with insecticide or plant growth regulator applications at the rate of 0.1 pound of boron per acre (0.5 lb per acre Solubor) beginning at early bloom, with three to five additional applications at the same rate in weekly intervals.
Secondary nutrients would include calcium (Ca), magnesium (Mg) and sulfur (S). This trio of nutrients, which may be identified as "the synthesizers," play key roles that are essential for plant growth and health. Cotton plants take up magnesium and sulfur in about the same quantities as phosphorus, a major nutrient. Calcium is required in even greater amounts.
Calcium functions include strengthening of cell walls to prevent their collapse, enhancing cell division and plant growth, protein synthesis, carbohydrate movement and balancing cell acidity. Increased susceptibility to seedling diseases and poor stalk strength are possible effects of calcium deficiency. All calcium is taken up from the soil.
Magnesium is essential for the production of the green pigment in chlorophyll. Chlorophyll is essential for photosynthesis, the conversion of sunlight into plant food (carbohydrate synthesis). The need for both calcium and magnesium is best determined by taking routine soil tests and applying lime (calcitic or dolomitic) as needed.
Sulfur is essential for the production of three amino acids, which are the building blocks in the synthesis of proteins. Assessing the need for sulfur is difficult. A soil test is of limited value since sulfate sulfur (SO4), the form used by plants, can be readily moved out of the root zone by percolating water.
Soil organic matter is the primary storehouse of sulfur in the soil. Thus, a low organic matter soil would suggest a possible need for added sulfur. The mobile nature of the sulfate ion indicates that a sandy soil with a low cation exchange capacity would also be a prime candidate for sulfur shortage. Common sulfur-bearing fertilizer materials include ammonium sulfate, ammonium thiosulfate (liquid), gypsum, potassium sulfate and sul-po-mag.
Micro means small. The essential micronutrients are elements that are needed in only small amounts. There are seven of these: boron (B), molybdenum (Mo), zinc (Zn), iron (Fe), manganese (Mn), copper (Cu) and chlorine (Cl).
Plants can suffer from a deficiency or an excess of any of these nutrients, depending on their soluble concentrations in the root zone. Micronutrient availability is influenced by soil pH. As the pH increases from 4.0 to 7.0, the solubility of boron, zinc, iron, manganese and copper decreases. In contrast, the solubility and availability of molybdenum increases as the pH increases. Liming to a pH of 6.0 to 6.5 usually strikes a favorable medium.
Soils can be tested for micronutrients, but testing is expensive and generally is not needed. Instances in which a micronutrient deficiency might exist would be: sandy soils low in organic matter; subsoils exposed due to grading or land leveling; cold and wet weather with slow breakdown of organic matter; alkaline soils; and very high levels of other nutrients (high phosphate levels can induce zinc deficiency).
Soils have two types of acidity:
- Active or soil solution acidity
- Reserve or exchangeable acidity
Active acidity can be measured by a pHs (salt buffered pH) soil test. A salt buffered pH is generally 0.5 pH units less than pH determined with distilled water.
All crops have a most favorable range of soil acidity for growth. For cotton, it is pHs of 6.0 to 6.5, with 6.5 being optimum. Agricultural limestone is used to increase the pHs, or lower the soil acidity. For agricultural purposes, the lime may be one of two types: "calcitic," which contains little or no magnesium carbonate, or "dolomitic," which has a magnesium carbonate content greater than about 5%. Dolomitic limestone is used primarily in those areas with known soil or crop magnesium deficiencies. Where magnesium deficiency is not a problem, calcitic limestone is normally used. The analysis of the limestone, and the "effective neutralizable material" (ENM) needed by the soil, will dictate the recommended tons of lime to apply per acre.
Some of the benefits derived by liming soils include:
- Improved availability of soil nutrients
- Increased efficiency of fertilizers
- Reduced availability and toxicity from aluminum and manganese
- Favorable microbial activity
- Better soil structure and tilth
- Improved activity of certain herbicides
An efficient fertilizer program can be developed by keeping in mind the time when different nutrients are needed and the fate of those nutrients when applied to the soil. Cotton needs for nitrogen are greatest during boll filling, but carry-over into harvest is detrimental. Phosphorus is needed all season long, but the ability of roots to extract phosphorus is reduced in cool spring soils, justifying "at planting" fertilizer applications for increased availability. The heaviest demand for potassium and boron occurs during boll filling. Phosphorus, potassium, calcium and magnesium stay where they are placed until that soil zone is disturbed; but nitrogen, boron and sulfur are vulnerable to losses from the root zone prior to plant uptake.