Nitrogen
Nitrogen is an essential nutrient for plant growth, development and reproduction. Despite nitrogen being one of the most abundant elements on earth, nitrogen deficiency is probably the most common nutritional problem affecting plants worldwide – nitrogen from the atmosphere and earth's crust is not directly available to plants.Nitrogen in Plants
Healthy plants often contain 3 to 4 percent nitrogen in their above-ground tissues.
This is a much higher concentration compared to other nutrients. Carbon, hydrogen and
oxygen, nutrients that don’t play a significant role in most soil fertility
management programs, are the only other nutrients present in higher concentrations.
Nitrogen is so vital because it is a major component of chlorophyll, the compound by which plants use sunlight energy to produce sugars from water and carbon dioxide (i.e., photosynthesis). It is also a major component of amino acids, the building blocks of proteins. Without proteins, plants wither and die. Some proteins act as structural units in plant cells while others act as enzymes, making possible many of the biochemical reactions on which life is based. Nitrogen is a component of energy-transfer compounds, such as ATP (adenosine triphosphate). ATP allows cells to conserve and use the energy released in metabolism. Finally, nitrogen is a significant component of nucleic acids such as DNA, the genetic material that allows cells (and eventually whole plants) to grow and reproduce. Without nitrogen, there would be no life as we know it.
Nitrogen is so vital because it is a major component of chlorophyll, the compound by which plants use sunlight energy to produce sugars from water and carbon dioxide (i.e., photosynthesis). It is also a major component of amino acids, the building blocks of proteins. Without proteins, plants wither and die. Some proteins act as structural units in plant cells while others act as enzymes, making possible many of the biochemical reactions on which life is based. Nitrogen is a component of energy-transfer compounds, such as ATP (adenosine triphosphate). ATP allows cells to conserve and use the energy released in metabolism. Finally, nitrogen is a significant component of nucleic acids such as DNA, the genetic material that allows cells (and eventually whole plants) to grow and reproduce. Without nitrogen, there would be no life as we know it.
Structure of an Amino Acid
Soil Nitrogen
Soil nitrogen exists in three general forms: organic nitrogen compounds, ammonium
(NH4+) ions and nitrate (NO3-) ions.
At any given time, 95 to 99 percent of the potentially available nitrogen in the soil is in organic forms, either in plant and animal residues, in the relatively stable soil organic matter, or in living soil organisms, mainly microbes such as bacteria. This nitrogen is not directly available to plants, but some can be converted to available forms by microorganisms. A very small amount of organic nitrogen may exist in soluble organic compounds, such as urea, that may be slightly available to plants.
At any given time, 95 to 99 percent of the potentially available nitrogen in the soil is in organic forms, either in plant and animal residues, in the relatively stable soil organic matter, or in living soil organisms, mainly microbes such as bacteria. This nitrogen is not directly available to plants, but some can be converted to available forms by microorganisms. A very small amount of organic nitrogen may exist in soluble organic compounds, such as urea, that may be slightly available to plants.
The majority of plant-available nitrogen is in the inorganic forms NH4+
and NO3- (sometimes called mineral nitrogen). Ammonium ions bind to the
soil's negatively charged cation exchange complex (CEC) and behave much like
other cations in the soil. Nitrate ions do not bind to the soil solids because they
carry negative charges, but exist dissolved in the soil water, or precipitated as
soluble salts under dry conditions.
Natural Sources of Soil Nitrogen
The nitrogen in soil that might eventually be used by plants has two sources:
nitrogen- containing minerals and the vast storehouse of nitrogen in the atmosphere.
The nitrogen in soil minerals is released as the mineral decomposes. This process is
generally quite slow, and contributes only slightly to nitrogen nutrition on most
soils. On soils containing large quantities of NH4+-rich clays (either
naturally occurring or developed by fixation of NH4+ added as
fertilizer), however, nitrogen supplied by the mineral fraction may be significant in
some years.
Atmospheric nitrogen is a major source of nitrogen in soils. In the atmosphere, it
exists in the very inert N2 form and must be converted before it becomes
useful in the soil. The quantity of nitrogen added to the soil in this manner is
directly related to thunderstorm activity, but most areas probably receive no more
than 20 lb nitrogen/acre per year from this source.
Bacteria such as Rhizobia that infect (nodulate) the roots of, and receive much food energy
Bacteria such as Rhizobia that infect (nodulate) the roots of, and receive much food energy
from, legume plants can fix much more nitrogen per year (some well over 100 lb
nitrogen/acre). When the quantity of nitrogen fixed by Rhizobia exceeds that needed
by the microbes themselves, it is released for use by the host legume plant. This is
why well-nodulated legumes do not often respond to additions of nitrogen fertilizer.
They are already receiving enough from the bacteria.
The Nitrogen Cycle
Nitrogen can go through many transformations in the soil. These transformations are
often grouped into a system called the nitrogen cycle, which can be presented in
varying degrees of complexity. The nitrogen cycle is appropriate for understanding
nutrient and fertilizer management. Because microorganisms are responsible for most
of these processes, they occur very slowly, if at all, when soil temperatures are
below 50° F, but their rates increase rapidly as soils become warmer.
The heart of the nitrogen cycle is the conversion of inorganic to organic nitrogen, and vice versa. As microorganisms grow, they remove H4+ and NO3- from the soil’s inorganic, available nitrogen pool, converting it to organic nitrogen in a process called immobilization. When these organisms die and are decomposed by others, excess NH4+ can be released back to the inorganic pool in a process called mineralization. Nitrogen can also be mineralized when microorganisms decompose a material containing more nitrogen than they can use at one time, materials such as legume residues or manures. Immobilization and mineralization are conducted by most microorganisms, and are most rapid when soils are warm and moist, but not saturated with water. The quantity of inorganic nitrogen available for crop useoften depends on the amount of mineralization occurring and the balance between mineralization and immobilization.
Ammonium ions (NH4+) not immobilized or taken up quickly by higher plants are usually converted rapidly to NO3- ions by a process called nitrification. This is a two-step process,during which bacteria called Nitrosomonas convert NH4+ to nitrite (NO2-), and then other bacteria, Nitrobacter, convert the NO2- to NO3-. This process requires a well-aerated soil and occurs rapidly enough that one usually finds mostly NO3- rather than NH4+ in soils during the growing season.
The heart of the nitrogen cycle is the conversion of inorganic to organic nitrogen, and vice versa. As microorganisms grow, they remove H4+ and NO3- from the soil’s inorganic, available nitrogen pool, converting it to organic nitrogen in a process called immobilization. When these organisms die and are decomposed by others, excess NH4+ can be released back to the inorganic pool in a process called mineralization. Nitrogen can also be mineralized when microorganisms decompose a material containing more nitrogen than they can use at one time, materials such as legume residues or manures. Immobilization and mineralization are conducted by most microorganisms, and are most rapid when soils are warm and moist, but not saturated with water. The quantity of inorganic nitrogen available for crop useoften depends on the amount of mineralization occurring and the balance between mineralization and immobilization.
Ammonium ions (NH4+) not immobilized or taken up quickly by higher plants are usually converted rapidly to NO3- ions by a process called nitrification. This is a two-step process,during which bacteria called Nitrosomonas convert NH4+ to nitrite (NO2-), and then other bacteria, Nitrobacter, convert the NO2- to NO3-. This process requires a well-aerated soil and occurs rapidly enough that one usually finds mostly NO3- rather than NH4+ in soils during the growing season.
The nitrogen cycle contains several routes by which plant-available nitrogen
can be lost from the soil. Nitrate-nitrogen is usually more subject to loss
than is ammonium-nitrogen. Significant loss mechanisms include leaching,
denitrification, volatilization and crop removal.
The nitrate form of nitrogen is so soluble that it leaches easily when excess water percolates through the soil. This can be a major loss mechanism in coarse-textured soils where water percolates freely, but is less of a problem in finer-textured, more impermeable soils, where percolation is very slow.
These latter soils tend to become saturated easily, and when microorganisms exhaust the free oxygen supply in the wet soil, some obtain it by decomposing NO3-. In this process, called denitrification, NO3- is converted to gaseous oxides of nitrogen or to N2 gas, both unavailable to plants. Denitrification can cause major losses
The nitrate form of nitrogen is so soluble that it leaches easily when excess water percolates through the soil. This can be a major loss mechanism in coarse-textured soils where water percolates freely, but is less of a problem in finer-textured, more impermeable soils, where percolation is very slow.
These latter soils tend to become saturated easily, and when microorganisms exhaust the free oxygen supply in the wet soil, some obtain it by decomposing NO3-. In this process, called denitrification, NO3- is converted to gaseous oxides of nitrogen or to N2 gas, both unavailable to plants. Denitrification can cause major losses
of nitrogen when soils are warm and remain saturated for more than a few
days.
Losses of NH4+ nitrogen are less common and occur mainly by volatilization. Ammonium ions are basically anhydrous ammonia (NH3) molecules with an extra hydrogen ion (H+) attached. When this extra H+ is removed from the NH4 ion by another ion such as hydroxyl (OH-), the resulting NH3 molecule can evaporate, or volatilize from the soil. This mechanism is most important in high-pH soils that contain large quantities of OH- ions.
Crop removal represents a loss because nitrogen in the harvested portions of the crop plant is removed from the field completely. The nitrogen in crop residues is recycled back into the system, and is better thought of as immobilized rather than removed. Much is eventually mineralized and may be reutilized by a crop.
Losses of NH4+ nitrogen are less common and occur mainly by volatilization. Ammonium ions are basically anhydrous ammonia (NH3) molecules with an extra hydrogen ion (H+) attached. When this extra H+ is removed from the NH4 ion by another ion such as hydroxyl (OH-), the resulting NH3 molecule can evaporate, or volatilize from the soil. This mechanism is most important in high-pH soils that contain large quantities of OH- ions.
Crop removal represents a loss because nitrogen in the harvested portions of the crop plant is removed from the field completely. The nitrogen in crop residues is recycled back into the system, and is better thought of as immobilized rather than removed. Much is eventually mineralized and may be reutilized by a crop.
Plant Nitrogen Needs and Uptake
Plants absorb nitrogen from the soil as both NH4+ and NO3- ions, but because nitrification is so pervasive in agricultural soils, most of the nitrogen is taken up as nitrate. Nitrate moves freely toward plant roots as they absorb water. Once inside the plant, NO3- is reduced to an NH2 form and is assimilated to produce more complex compounds. Because plants require very large quantities of nitrogen, an extensive root system is essential to allowing unrestricted uptake. Plants with roots restricted by compaction may show signs of nitrogen deficiency even when adequate nitrogen is present in the soil.| Crop | Yield Per Acre | N |
|---|---|---|
| Alfalfa | 8 tons | 432 |
| Corn | 180 bu | 180 |
| Soybeans | 60 bu | 294 |
| Spring Wheat | 80 bu | 176 |
| Winter Wheat | 80 bu | 152 |
Source: IPNI
Most plants take nitrogen from the soil continuously throughout their lives, and nitrogen
demand usually increases as plant size increases. A plant supplied with adequate nitrogen
grows rapidly and produces large amounts of succulent, green foliage. Providing adequate
nitrogen allows an annual crop, such as corn, to grow to full maturity, rather than
delaying it. A nitrogen-deficient plant is generally small and develops slowly because it
lacks the nitrogen necessary to manufacture adequate structural and genetic materials. It
is usually pale green or yellowish because it lacks adequate chlorophyll. Older leaves
often become necrotic and die as the plant moves nitrogen from less important older
tissues to more important younger ones.
On the other hand, some plants may grow so rapidly when supplied with excessive nitrogen that they develop protoplasm faster than they can build sufficient supporting material in cell walls. Such plants are often rather weak and may be prone to mechanical injury. Development of weak straw and lodging of small grains are an example of such an effect.
On the other hand, some plants may grow so rapidly when supplied with excessive nitrogen that they develop protoplasm faster than they can build sufficient supporting material in cell walls. Such plants are often rather weak and may be prone to mechanical injury. Development of weak straw and lodging of small grains are an example of such an effect.
Fertilizer Management
Nitrogen Cycle
Nitrogen fertilizer rates are determined by the crop to be grown, yield goal and
quantity of nitrogen that might be provided by the soil. Rates needed to achieve
different yields with different crops vary by region, and such decisions are usually
based on local recommendations and experience.
Factors that Determine the Quantity of Nitrogen Supplied by the Soil
- The quantity of nitrogen released from the soil organic matter
- The quantity of nitrogen released by decomposition of residues of the previous crop
- Any nitrogen supplied by previous applications of organic waste
- Any nitrogen carried over from previous fertilizer applications.
Soil testing is being suggested more often as an alternative to taking nitrogen credits. Testing soils for nitrogen has been a useful practice in the drier regions of the Great Plains for many years,
and in that region, fertilizer rates are often adjusted to account for NO3-
found in the soil prior to planting. In recent years, there has been some interest in
testing cornfields for NO3- in the more humid regions of the eastern
United States and Canada, utilizing samples taken in late spring, after crop
emergence, rather than before planting. This strategy, the pre-side-dress nitrogen
soil test (PSNT), has received a great deal of publicity and seems to provide some
indication of whether additional side-dressed nitrogen is needed or not.
Fertilizer Placement
Placement decisions should maximize availability of nitrogen to crops and minimize potential losses. A plant’s roots usually will not grow across the root zone of another plant, so nitrogen must be placed where all plants have direct access to it. Broadcast applications accomplish this objective. Banding does also when all crop rows are directly next to a band. For corn, banding anhydrous ammonia or urea ammonium nitrate (UAN) in alternate row middles is usually as effective as banding in each middle because all rows have access to the fertilizer.Moist soil conditions are necessary for nutrient uptake. Placement below the soil surface can increase nitrogen availability under dry conditions because roots are more likely to find nitrogen in moist soil with such placement. Injecting side-dressed UAN may produce higher corn yields than surface application in years when dry weather follows side-dressing. In years when rainfall occurs shortly after application, subsurface placement is not as critical.
Subsurface placement is normally used to control nitrogen losses. Anhydrous ammonia must be placed and sealed below the surface to eliminate direct volatilization losses of the gaseous ammonia. Volatilization from urea and UAN solutions can be controlled by incorporation or injection. Incorporating urea materials (mechanically or by rainfall shortly after application) is especially important in no-till situations in which volatilization is aggravated by large amounts of organic material on the soil surface. Applying small amounts of "starter" nitrogen as UAN in herbicide sprays, however, is usually of little concern.
Placing nitrogen with phosphorus often increases phosphorus uptake, particularly when nitrogen is in the NH4+ form and the crop is growing in an alkaline soil. The reasons for the effect are not completely clear, but may be due to nitrogen increasing root activity and potential for phosphorus uptake, and nitrification of NH4+ providing acidity, which enhances phosphorus solubility.
Timing of Nutrient Application
Timing has a major effect on the efficiency of nitrogen management systems. Nitrogen should be applied to avoid periods of significant loss and to provide adequate nitrogen when the crop needs it most. Wheat takes up most of its nitrogen in the spring and early summer, and corn absorbs most nitrogen in midsummer, so ample availability at these times is critical. If losses are expected to be minimal, or can be effectively controlled, applications before or immediately after planting are effective for both crops. If significant losses, particularly those due to denitrification or leaching, are anticipated, split applications, in which much of the nitrogen is applied after crop emergence, can be effective in reducing losses. Fall applications for corn can be used on well-drained soils, particularly if the nitrogen is applied as anhydrous ammonia amended with N-Serve®; however, fall applications should be avoided on poorly drained soils, due to an almost unavoidable potential for significant denitrification losses. When most of a crop’s nitrogen supply will be applied after significant crop growth or positioned away from the seed row (anhydrous ammonia or UAN banded in row middles), applying some nitrogen easily accessible to the seedling at planting ensures that the crop will not become nitrogen deficient before gaining access to the main supply of nitrogen.Minimizing Fertilizer Losses
The major mechanisms for nitrogen fertilizer loss are denitrification, leaching and volatilization. Denitrification and leaching occur under very wet soil conditions, while volatilization is most common when soils are only moist and are drying.Practices for Avoiding Nitrogen Fertilizer Losses
Using an NH4+ source of nitrogen acidifies the soil because the hydrogen ions (H+) released during nitrification of the NH4+ are the major cause of acidity in soils. Over time, acidification and lowering of soil pH can become significant.Nitrogen fertilizers containing NO3- but no NH4+ make the soil slightly less acidic over time, but are generally used in much lesser quantities than the others. The acidification due to NH4-nitrogen is a significant factor in the acidification of agricultural fields, but can easily be controlled by normal liming practices.
| Material | % Nitrogen | Approx. CaCO3 Equivalent lb/ton of material* | Per LB of N |
|---|---|---|---|
| Anhydrous Ammonia | 82% | -2,960 | 1.80 |
| Ammonia Sulfate | 21% | -2,200 | 5.20 |
| Urea | 46% | -1,680 | 1.83 |
| Diammonium Phosphate | 18% | -1,400 | 3.8 |
| Urea-Form | 38% | -1,360 | 1.79 |
| Monoammonium Phosphate | 10% | -1,300 | 6.5 |
| Ammonium Nitrate | 33.5% | -1,180 | 116 |
| Nitrogen Solutions | 19-49% | -750 to -1,760 | 197-179 |
| Calcium Nitrate | 15% | +400 | None |
| Potassium Nitrate | 13% | +580 | None |
| Sodium Nitrate | 16% | +520 | None |
*A minus sign indicates the number of pounds of calcium carbonate equivalent needed
to neutralize the acid formed when 1 ton of the material is added to the soil. (Note
that approximately two times this amount would be required if ag-lime is used.) A
plus sign indicates the material is basic in nature.
Fertilizing Legumes with Nitrogen
Because the Rhizobia bacteria that infect legume roots normally supply adequate nitrogen to the host plant, well-nodulated legumes rarely respond to additions of nitrogen fertilizer. Occasionally, however, soybeans may respond to applications of nitrogen late in the season, presumably because nitrogen fixation in the nodules has declined significantly. Such responses are quite erratic, though, and late-season applications of nitrogen to soybeans are not routinely recommended. The amount of atmospheric nitrogen fixed by non-symbiotic soil organisms varies with soil types, organic matter present and soil pH.| Crop | LB/acre Nitrogen |
|---|---|
| Alfalfa | 196 |
| Ladino Clover | 178 |
| Sweet Clover | 116 |
| Red Clover | 112 |
| White Clover | 103 |
| Soybeans | 98 |
| Cowpeas | 89 |
| Lespedeza | 85 |
| Vetch | 80 |
| Garden Peas | 71 |
| Winter Peas | 54 |
| Peanuts | 42 |
Adapted from "Fertilizers and Soil Amendments" by Follett, Murphy and Donahue.
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