Form Matters

Nitrogen comes in many forms; which you choose — and what you apply with it — can significantly affect plant and soil health

The fixation of nitrogen from the atmosphere is critical for life on earth. While nitrogen constitutes 78 percent of the air we breathe, that molecular farm is extremely inert, not wanting to interact with other molecules. Biological processes transform this inert nitrogen into reactive nitrogen, which can be assimilated into the bodies of living organisms. 

While in a reactive form, a nitrogen ion may be found in any number of nitrogen-containing compounds. Eventually, the nitrogen ion will end up back in the atmosphere in an inert form, thus completing the nitrogen cycle. 

Nitrogen is particularly essential for plants — it is part of all amino acids, nucleic acids, enzymes and chlorophyl. Prior to the 20th century, agriculture depended solely on nitrogen-fixing microbes to make atmospheric nitrogen available to living organisms. 

The discovery of the Haber-Bosch process marked a radical shift in how we acquire and use nitrogen. This method produces ammonia from purified atmospheric nitrogen. The process is energy intensive, accounting for 1 to 2 percent of global energy consumption. The amount of nitrogen fixed through industrial means is now nearly as great as what is fixed by biology globally. 

This has had a major impact on the nitrogen cycle. Nitrogen fertilizer accounts for a major proportion of agricultural pollution. Groundwater contamination, oceanic dead zones, toxic algae blooms, and ozone-destroying gases are all the result of excess nitrogen fertilizer use. Rising energy prices and continued environmental degradation has put pressure on farmers to evaluate and reconsider how they use nitrogen. 

By understanding the different forms of nitrogen and how to use nitrogen fertilizers most efficiently, farmers can improve profitability while also improving environmental health.

Excess and Deficiency

Plants deficient in nitrogen will show a yellow or pale-green coloring called chlorosis. They will also appear thin and stunted. Protein content of the plant will be low and sugar content will be high because there is not enough nitrogen available to form carbon compounds into protein. Nitrogen is mobile within the plant, meaning the plant can translocate nitrogen to the parts that needs it most. In nitrogen-deficient plants, old leaves tend to die off because the nitrogen they contain is needed for new growth. 

An oversupply of nitrogen results in weak, watery plant growth. Plant cells become turgid and elongated. Susceptibility to insect attack is increased, and the nutrient concentration of the crop is diluted. Excess nitrogen can also lead to elevated levels of nitrates in plant tissue. This poses a health risk to both humans and livestock, and it makes the plant more susceptible to disease and insect pressure. 

Farmers can control nitrogen levels in plants by altering their nitrogen source, application rate, timing of application, and the application method. 

Nitrogen Sources

Nitrate (NO^–₃). Nitrate is one of the two main forms of mineral nitrogen absorbed by plants. It is a negatively charged ion, so it is unable to bind to the soil colloid. This makes nitrate prone to leaching. Leached nitrate wastes nutrients, acidifies the soil and pollutes ground water. Leached nitrate also co-leaches calcium, magnesium and potassium. 

Due to nitrification, nitrate is the most common form of mineral nitrogen in the soil. While nitrate is absorbed rapidly by the plant, it is metabolically inefficient. For a plant to use nitrate, it must be converted to ammonium after it is absorbed. This conversion process uses water and energy supplied through photosynthesis. A plant absorbing nitrogen as nitrate can use as much as 25 percent more energy than it would have if the nitrogen was in the form of ammonium. 

While some of the energy is used to convert nitrate to ammonium, a proportion of the energy expended by the plant is used to regulate the redox potential and pH of the rhizosphere. Nitrate has an oxidizing effect and lowers the pH of the soil. This impacts the availability of other nutrients because they will not be in a plant available form if the redox potential and pH are not within a certain range. 

In addition to increased energy expenditure, the nitrate to ammonium conversion requires water. For every one molecule of nitrogen in nitrate, four molecules of water are needed to convert it to the ammonium form. In this way, the source of nitrogen fertilizer can significantly increase a crop’s susceptibility to drought stress. Nitrate-containing fertilizer sources include ammonium nitrate, potassium nitrate, and calcium nitrate. Excessive applications of manure can also contain appreciable amounts of nitrate.

Ammonia (NH₃). All synthetic fertilizers begin as ammonia. Through industrial processes, atmospheric nitrogen is converted into ammonia gas. It is then made into anhydrous ammonia. 

Anhydrous ammonia is highly concentrated and toxic. From a soil health perspective, it is one of the worst nitrogen fertilizer sources. Before it can be used by plants, bacteria must convert ammonia into ammonium. In the process, some of the ammonia is lost through volatilization, especially in sandy soil. 

Anhydrous ammonia kills soil life, solubilizes humus, dries the soil and alters pH near the injection site. The deleterious effects of anhydrous ammonia make it a poor choice for regenerative farmers.

Ammonium (NH⁺₄). Ammonium is the second of the primary forms of mineral nitrogen absorbed by plants. Unlike nitrate, ammonium ions are positively charged. Ammonium is less prone to leaching because it will bind to the soil colloid; however, much of the ammonium in the soil will be converted into nitrate through nitrification. Another portion of ammonium will be lost as ammonia. 

Chemicals that inhibit nitrification can be applied, but the use of biology-suppressing chemicals runs counter to the aims of regenerative agriculture. Ammonium can also be fixed in some clay particles such that it becomes unavailable to plants. While excess ammonium applications are still prone to leaching, it is more metabolically efficient than nitrate. This is because the plant does not have to undergo the nitrate to ammonium conversion. 

Ammonium is already in a form that the plant can use to make amino acids. This leaves more energy and water available for plant growth. Ammonium also has a reducing effect on the soil. This can be beneficial because cultivated land is often highly oxidized. The synthetic fertilizer market is full of ammonium-based products, including ammonium sulfate, urea ammonium nitrate, ammonium thiosulfate, monoammonium phosphate and diammonium phosphate. 

Organic growers have historically lacked concentrated nitrogen fertilizers. New processes have recently been developed to distill liquid ammonium from hog manure for use in certified organic production (see sidebar).