Ammonia (NH3) is among the most important chemicals produced by humans and has a promising future in sustainable energy applications besides being used in fertilizer production.
Ammonia (NH3) is among the most important chemicals produced by humans and has a promising future in sustainable energy applications besides being used in fertilizer production. Unfortunately, so far, the only realistic way that exists to produce ammonia at an industrial scale is through the Haber–Bosch process. This technique, discovered in the 19th century, is very energy-intensive and environmentally unfriendly; about 2% of the yearly global CO2 emissions come from Haber–Bosch processes.
“Considering the threats posed by global warming, it is high time we swap to an ammonia synthesis route with zero CO2 emissions,” says Professor Sangaraju Shanmugam from Daegu Gyeongbuk Institute of Science and Technology (DGIST), Korea. Shanmugam and colleagues at DGIST have been working on finding new ways to produce ammonia through electrochemical reactions at room temperature using the nitrogen (N2) naturally present in air, a process technically known as ‘electrocatalytic fixation of atmospheric N2.’
Although various research groups have successfully developed catalysts for electrochemical cells with high ammonia production rates, many suffer from low efficiency and selectivity towards N2. Others require precious metals or complex synthesis processes, which limits their applicability on an industrial scale. In a recent study published in Applied Catalysis B: Environmental, DGIST scientists led by Prof. Shanmugam tackled all these issues with a novel catalyst for electrochemical ammonia synthesis.
Their approach is based on molybdenum nitride (Mo2N) nanoparticles, which share electrical properties with the enzyme nitrogenase that some bacteria use to produce ammonia in nature. Nanoparticles alone don’t make the cut; however, because they tend to stick to each other, this agglomeration reduces the total surface area that is exposed to N2 and thus hinders the catalyst’s performance. To combat this problem, the scientists produced two-dimensional hexagonal boron nitride (h-BN) sheets and tailored them to contain defects. These defects—boron and nitrogen vacancies—provided sites for the Mo2N nanoparticles to anchor themselves without agglomerating much.
Read more at DGIST (Daegu Gyeongbuk Institute of Science and Technology)
Image: Over 200 million tons of ammonia are produced each year, most of which is used as a fertilizer. Thus, it is essential to find scalable ecofriendly synthesis routes to satisfy the global demand while protecting the environment. (Credit: Freepik)