It can be found in fertilizer products such as YaraBela, YaraMila and others. It explains the carbon footprint from production, transportation and application, to growing of crops, their consumption as food, feed or bio-energy, and the protection of natural CO2 sinks such as forests and wetlands.
To make different GHGs comparable, they are converted into CO2 equivalents (CO2-eqv).
1 kg N2O = 296 kg CO2 eqv
Which means it has a 296 times stronger effect on the climate than CO2. All data are expressed per kg of nitrogen applied.
When operating with ‘Best Available Technique’ (BAT) ammonia and nitric acid plants, the total carbon footprint of AN is 3.6 kg CO2-eqv per kg N. Ammonia Production Binding nitrogen from the air requires energy. Natural gas is the most efficient energy source. Yara plants are among the best performers in terms of energy efficiency worldwide.
Nitric acid is used for making AN-based fertilizers. Its production releases N2O. Catalytic cleansing developed by Yara reduces N2O emissions below BAT level.
AN solutions made from ammonia and nitric acidare granulated or prilled to form high-quality solid fertilizer. Solidification needs energy.
Ammonium nitrate is transported by ship, barge, road or rail.
European average: 0.1 kg CO2 per kg N
Optimize logistics chain from production sites to farmers
Nitrogen, whether from organic or inorganic sources, is subject to natural microbial conversion in the soil. During this process N2O can be lost to the air. In addition, CO2 is also released by liming and farming machinery.
Plants capture large amounts of CO2 during growth. Optimum fertilization can increase biomass production, and thus CO2 uptake, by a factor of 4-5 compared to fields that remain long-term unfertilized. For example, at a yield of 8 t/ha achieved with 170 kg N/ha, the grain fixes 12 800 kg/ha of CO2. This corresponds to 75 kg of CO2 fixed per kg of N applied.
Most of the biomass produced is consumed as food or feed. CO2 fixation is therefore only short term and cannot be considered a saving on a global scale. The balance is different for bio-energy since it avoids the burning of fossil fuels. For example, using biomass instead of mineral oil for heating purposes reduces the CO2 emission by as much as 70-80%.
Forests and wetlands store 2-8 times more CO2 than croplands. Land use change, mainly due to burning of tropical forests, is a large source of CO2 emissions, accounting for 20% of manmade CO2 emissions. Preserving tropical and boreal forests is the most important contribution to mitigate climate change.