Ammonia pollution
Ammonia pollution is pollution by the chemical ammonia – a compound of nitrogen and hydrogen which is a byproduct of agriculture and industry. Common forms include air pollution by the ammonia gas emitted by rotting agricultural slurry and fertilizer factories while natural sources include the burning coal mines of Jharia, the caustic Lake Natron and the guano of seabird colonies. Gaseous ammonia reacts with other pollutants in the air to form fine particles of ammonium salts, which affect human breathing. Ammonia gas can also affect the chemistry of the soil on which it settles and will, for example, degrade the conditions required by the sphagnum moss and heathers of peatland.
Ammonia also has effects on aquatic ecosystems and decreases the biodiversity. Ammonia is toxic to aquatic life which leads to increased amounts of fish deaths. Ammonia pollution also leads to eutrophication. Eutrophication is the growth of algae that kills other aquatic life and creates dead zones. Ammonia pollution affects freshwater and salt water ecosystems differently due to physical and chemical differences.
Ammonia detection is facilitated through the use of filter packs and fabric denuders. Techniques such as satellite imaging and rainwater analysis are also used. Much is still unknown about the impact of ammonia pollution, but rising emission rates concern scientists. The level of ammonia in the atmosphere was more than twice as large in 2010 as it was in 1940. Ammonia is now recognized by many countries as a major pollutant and some have begun taking steps to limit their emissions.
Effects
Ammonia decreases the biodiversity of terrestrial and aquatic ecosystems and also forms aerosols in the atmosphere which can cause human health complications if inhaled.Biodiversity
Gaseous ammonia emissions enter Earth's soil and water through both wet and dry deposition. Aqueous ammonia, another form of the compound, may seep directly into the ground or flow into aquatic ecosystems. Both terrestrial and aquatic ammonia pollution decrease biodiversity mainly through the process of nitrification.Terrestrial Effects
In terrestrial settings, ammonia increases soil acidity and causes eutrophication. Both of these occur as a direct result of nitrification. In this process, ammonia is converted into nitrate by bacteria performing the following two step reaction:Step 1: Ammonia is oxidized into nitrite by:
Step 2: Nitrite is oxidized into nitrate
The products of this reaction include hydrogen ions which lower the soil pH and lead to acidification. Increased soil acidity in the ecosystem leads to decreased protection against cold temperatures, drought, disease, and invasive species. The other product, nitrate, is a key nutrient for plant growth. This excess nitrate from ammonia nitrification favors nitrophilous plants and disadvantages others. For example, an increase in nitrophilous plant populations shade other plants from necessary sunlight. Sensitive plant groups such as lichen and moss are particularly susceptible to ammonia pollution and habitats such as bogs, peatlands, grasslands, heathlands, and forests are mainly affected.
In livestock, high ammonia concentrations has been linked to ascites, gastrointestinal irritation and respiratory disease. These issues are easily observable in poultry, specifically turkeys. Turkeys have been shown to have trachea irritation at 10 ppm and at above 20 ppm they have an increased rate of contracting Newcastle disease. Above 25 ppm, growth rate and body weight is reduced. Above 50 ppm, there are increases levels of keratoconjunctivitis and tracheitis. Such trachea and lung complications make turkeys more prone to contracting infections like E. coli.
Aquatic effects
Ammonia seeps into aquatic ecosystem in many different ways from both anthropogenic and natural sources. Ammonia is toxic to most aquatic life including fish, corals, and planktonic crustaceans. Ammonia can have 2 different forms in water.This reaction is showing how ammonia changes into ammonium in water and generates a hydroxide ion. The form that the ammonia takes in the water also depends on the pH and temperature. Waters that are more basic have more ammonia compared to the amount of ammonium. Ammonia is directly toxic to aquatic life while ammonium is not. This is because ammonia can diffuse across cell membranes but ammonium can't. This means that the more basic the waters, the more toxic ammonia pollution will be to the aquatic life.
Freshwater effects
systems are commonly limited by nitrogen. This means that increases in nitrogen in freshwater ecosystems can increase the primary productivity of plants and algae. When too much nitrogen is added to the water, the algae in the water can increase their output so rapidly that eutrophication occurs. Eutrophication is an increase in algal growth which causes the oxygen dissolved in the water to decrease. This decrease creates hypoxic waters that cause the death of other aquatic life like fish. This decreases the amount of biodiversity in the waters where this occurs.Ammonia is also directly toxic to fish and as the amount of ammonia increases, the more that accumulates in their bodies and it becomes harder to for the animals to remove it from their bodies. Freshwaters tend to have a wide range of pH values from 6.5 to 9. Freshwaters that have a higher pH would be more sensitive to increases in ammonia due to the balance between ammonia and ammonium and the aquatic life would be more affected. The ammonia causes stress on the fish and damages internal organs which will eventually lead to death.
Salt water effects
systems are also commonly limited by nitrogen. Eutrophication can also occur in salt water due to increases in ammonia available, however it is more common in freshwaters because they have limited circulation and shallower waters. The pH of the ocean tends to be about 8.1 which means that ammonium is more abundant than ammonia, however, when the pH increases, as it does when primary production rates are high, ammonia becomes more abundant. This also means that there are more toxic effects than in freshwater that can be more acidic.Ammonia in salt water ecosystems will have similar effects on fish as ammonia in freshwater ecosystems. Another aquatic animal that is affected by increasing amounts of ammonia is coral. Coral are very important for diversity in oceans and increasing concentrations of ammonia in the water is harming the bacteria that are found on the coral. The coral and bacteria are in a symbiotic relationship and the death of the bacteria leads to the bleaching of the coral and death. Corals support biodiversity in the ocean and the loss of coral reefs leads to a decrease in biodiversity.
Human health
Beyond its impact on ecosystems, ammonia pollution poses significant risks to human health. Gaseous ammonia that is not deposited forms aerosols by combining with other emissions such as sulfur dioxide and nitrogen oxides. Atmospheric reactions among sulfur dioxide, nitrogen oxides, intermediate products, and other gases eventually result in formation of ammonium nitrate and ammonium bisulfate by the following:These resulting ammonium aerosols are classified as fine particulate matter. The small size of PM2.5 particles allows them to enter the lungs and bloodstream through inhalation. Ammonium particles can then cause complications including asthma, lung cancer, cardiovascular issues, birth defects, and premature death in humans. The smaller ammonium PM2.5 can also travel further distances when compared to unreacted ammonia in the atmosphere. Some countries like China have focused on reducing SO2 and NOX emissions, however increased NH3 pollution still results in PM2.5 formation and reduces air quality. Despite efforts to reduce sulfur dioxide and nitrogen oxides emissions, the persistent presence of ammonia pollution continues to pose challenges to air quality management, particularly in densely populated areas like urban centers