Sign up for our daily Newsletter and stay up to date with all the latest news!

Subscribe I am already a subscriber

You are using software which is blocking our advertisements (adblocker).

As we provide the news for free, we are relying on revenues from our banners. So please disable your adblocker and reload the page to continue using this site.

Click here for a guide on disabling your adblocker.

Sign up for our daily Newsletter and stay up to date with all the latest news!

Subscribe I am already a subscriber
Carbon neutral fertiliser production and use to be discussed at Agri-TechE event 24th March

On-farm fertilizer production comes out of the box

“Current ammonia production facilities are huge factories, producing millions of tonnes of ammonia, and double that amount of carbon dioxide, says Guðbjörg Rist, CEO of Atmonia. 

Is it possible to produce nitrogen fertilizer on-farm? Would this reduce the agricultural sector’s greenhouse gas emissions? Early-stage agri-tech companies Atmonia and N2 Applied say yes. They have each developed an alternative approach to generating fertilizer, using renewable energy sources, operating from a shipping container, offering the potential for carbon-neutral production.

Food production accounts for 26% of global greenhouse gas emissions*. Changing the way we produce and use nitrogen fertilizer would make a significant difference to these headline-grabbing figures, and this is to be discussed at the Agri-TechE event “Putting the N in FarmiNg” on 24th March 2021.

Guðbjörg explains that current inorganic fertilizer production uses an energy-intensive process. “The Haber-Bosch process splits hydrogen from coal and natural gas, creating free hydrogen ions that combine with nitrogen gas in air to produce ammonia, a raw product for inorganic fertilizer production.

“Our process takes a completely different approach: it uses an electrochemical reaction to split nitrogen, which combines with hydrogen from air and water, removing the need for coal or natural gas. It also reduces the energy requirement, which can be sourced from renewables. “Our facility is designed to produce hundreds of tonnes of ammonia from a unit the size of a shipping container, creating a liquid fertilizer that can be produced close to the point of need.”

Another greenhouse gas, nitrous oxide (N2O), is released when synthetic nitrogen fertilizers are applied to soils. N2O and methane are also produced from the decomposition of animal manures under low oxygen conditions.

N2 Applied is tackling this issue by converting by-products like slurry into a valuable nitrogen-enriched organic liquid fertilizer. As a result of the process, the output, known as NEO, is slightly acidic, which increases its stability. This reduces the amount of ammonia released whilst eliminating methane emissions.

“Our technology can cut the carbon footprint of a dairy farm by 27% and produce a valuable organic fertiliser with three times the crop available nitrogen in slurry,” explain Chris Puttick of N2 Applied.

Nitrogen is found in different forms in the environment and total nitrogen (NH4, NO3 and NO2) needs to be considered within a nutrient management plan for the crop. This is particularly important where the farm lies within a nitrate vulnerable zone (NVZ). Trials of NEO have shown that the nitrogen available to the crop is three times higher than untreated slurry and when applied to a grass sward increased the yield by 41% over two cuts.

Work by Professor Andrew Neal of Rothamsted Research has shown that the way nitrogen is applied to the soil is also important. Results suggest that decades of artificial fertilizer inputs on UK soil without a corresponding return of organic matter have altered the balance of carbon and nitrogen in the soil, changing the way microbes get their energy, which has in turn altered the soil structure.

In the experiment, soil with high nitrogen content but low carbon content had an altered microbial community, which was associated with fewer pores and connectivity in the soil. As the pores close up, and oxygen in the soil is lost, microbes are forced to turn to nitrogen and sulfur compounds for their energy. This inefficient process drains nutrients from the soil and results in increased emissions of N2O.

For more information:

Publication date: