Nitrogen is the most critical element obtained by plants from the soil, to the exception of moist tropical forests where phosphorus is the
limiting soil nutrient, and
nitrogen deficiency often limits plant growth. Plants can use nitrogen as either the
ammonium cation (NH4+) or the anion
nitrate (NO3−). Plants are commonly classified as ammonium or nitrate plants according to their preferential nitrogen nutrition. Usually, most of the nitrogen in soil is bound within organic compounds that make up the
soil organic matter, and must be
mineralized to the ammonium or nitrate form before it can be taken up by most plants. However, symbiosis with
mycorrhizal fungi allow plants to get access to the organic nitrogen pool where and when mineral forms of nitrogen are poorly available. The total nitrogen content depends largely on the soil organic matter content, which in turn depends on
texture,
climate, vegetation,
topography, age and
soil management. Soil nitrogen typically decreases by 0.2 to 0.3% for every temperature increase by 10 °C. Usually, grassland soils contain more soil nitrogen than forest soils, because of a higher turnover rate of grassland organic matter. Cultivation decreases soil nitrogen by exposing soil organic matter to decomposition by microorganisms, most losses being caused by
denitrification, and soils under no-tillage maintain more soil nitrogen than tilled soils. Some
micro-organisms are able to metabolise organic matter and release ammonium in a process called
mineralisation. Others, called
nitrifiers, take free
ammonium or
nitrite as an intermediary step in the process of
nitrification, and oxidise it to
nitrate.
Nitrogen-fixing bacteria are capable of metabolising N2 into the form of
ammonia or related nitrogenous compounds in a process called
nitrogen fixation. Both ammonium and nitrate can be
immobilized by their incorporation into microbial living cells, where it is temporarily sequestered in the form of
amino acids and
proteins. Nitrate may be lost from the soil to the atmosphere when bacteria metabolise it to the gases NH3, N2 and N2O, a process called
denitrification. Nitrogen may also be
leached from the
vadose zone if in the form of nitrate, acting as a
pollutant if it reaches the
water table or
flows over land, more especially in agricultural soils under high use of nutrient fertilizers. Ammonium may also be sequestered in 2:1
clay minerals. A small amount of nitrogen is added to soil by
rainfall, to the exception of wide areas of North America and West Europe where the excess use of
nitrogen fertilizers and
manure has caused
atmospheric pollution by ammonia emission, stemming in
soil acidification and
eutrophication of soils and
aquatic ecosystems. In that form the nitrogen is said to be
immobilised. Later, when such bacteria die, they too are
mineralised and some of the nitrogen is released as ammonium and nitrate. Predation of bacteria by soil fauna, in particular
protozoa and
nematodes, play a decisive role in the return of immobilized nitrogen to mineral forms. If the C/N of fresh residues is less than 15, mineral nitrogen is freed to the soil and directly available to plants. Bacteria may on average add nitrogen per acre, and in an unfertilised field, this is the most important source of usable nitrogen. In a soil with 5% organic matter perhaps 2 to 5% of that is released to the soil by such decomposition. It occurs fastest in warm, moist, well aerated soil. The mineralisation of 3% of the organic material of a soil that is 4% organic matter overall, would release of nitrogen as ammonium per acre. In
nitrogen fixation,
rhizobium bacteria convert N2 to ammonia (NH3), which is rapidly converted to
amino acids, parts of which are used by the rhizobia for the synthesis of their own biomass proteins, while other parts are transported to the
xylem of the host plant.
Rhizobia share a
symbiotic relationship with host plants, since rhizobia supply the host with nitrogen and the host provides rhizobia with other nutrients and a safe environment. It is estimated that such symbiotic bacteria in the
root nodules of
legumes add 45 to 250 pounds of nitrogen per acre per year, which may be sufficient for the crop. Other, free-living nitrogen-fixing
diazotroph bacteria and
archaea live independently in the soil and release mineral forms of nitrogen when their dead bodies are converted by way of
mineralization. Some amount of atmospheric nitrogen is transformed by
lightnings in gaseous
nitric oxide (NO) and
nitrogen dioxide (NO2−). Nitrogen dioxide is soluble in water to form
nitric acid (HNO3) dissociating in H+ and NO3−. Ammonia, NH3, previously emitted from the soil, may fall with precipitation as nitric acid at a rate of about five pounds nitrogen per acre per year.
Sequestration When bacteria feed on soluble forms of nitrogen (ammonium and nitrate), they temporarily sequester that nitrogen in their bodies in a process called
immobilization. At a later time when those bacteria die, their nitrogen may be released as ammonium by the process of mineralization, sped up by predatory fauna. Protein material is easily broken down, but the rate of its decomposition is slowed by its attachment to the crystalline structure of clay and when trapped between the clay layers or attached to rough clay surfaces. The layers are small enough that bacteria cannot enter. Some organisms exude extracellular enzymes that can act on the sequestered proteins. However, those enzymes too may be trapped on the clay crystals, resulting in a complex interaction between proteins, microbial enzymes and mineral surfaces. Ammonium fixation occurs mainly between the layers of 2:1 type clay minerals such as
illite,
vermiculite or
montmorillonite, together with ions of similar
ionic radius and low
hydration energy such as
potassium, but a small proportion of ammonium is also fixed in the
silt fraction. Only a small fraction of soil nitrogen is held this way.
Losses Usable nitrogen may be lost from soils when it is in the form of
nitrate, as it is easily
leached, contrary to
ammonium which is easily fixed. Further losses of nitrogen occur by
denitrification, the process whereby soil bacteria convert nitrate (NO3−) to nitrogen gas, N2 or N2O. This occurs when poor
soil aeration limits free oxygen, forcing bacteria to use the oxygen in nitrate for their respiratory process. Denitrification increases when oxidisable organic material is available, as in
organic farming Denitrification may vary throughout a soil as the aeration varies from place to place. Denitrification may cause the loss of 10 to 20 percent of the available nitrates within a day and when conditions are favourable to that process, losses of up to 60 percent of nitrate applied as fertiliser may occur.
Ammonia volatilisation occurs when ammonium reacts chemically with an
alkaline soil, converting NH4+ to NH3. The application of ammonium fertiliser to such a field can result in volatilisation losses of as much as 30 percent. All kinds of nitrogen losses, whether by leaching or volatilization, are responsible for a large part of
aquifer pollution and
air pollution, with concomitant effects on
soil acidification and
eutrophication, a novel combination of environmental threats (acidity and excess nitrogen) to which extant organisms are badly adapted, causing severe biodiversity losses in natural ecosystems. == Phosphorus ==