Affiliation:
1. Department of Biosystems Engineering and Soil Science, The University of Tennessee, Knoxville, TN 37996, USA
Abstract
Synthetic nitrogen fertilizer is the backbone of modern agriculture, helping to feed ~50% of the world’s population. However, the current industrial production, distribution, and use of nitrogen fertilizers are built on an unsustainable foundation of fossil resources, and are energy-intensive, environmentally polluting, and inefficient in their usage. With the rapidly declining cost of renewable electricity, such as solar and wind, it is time to develop and implement the decentralized production and application of nitrogen fertilizer with nonthermal plasma technologies. Such locally sourced production at the farm site, using only air and water as feedstock, circumvents the need for the extensive capital investment and infrastructure required for synthetic nitrogen fertilizer production and storage, as well as the complex and costly distribution networks. It will be adaptive to the intermittency of the solar/wind electricity supply, leave no carbon footprint, and also have the advantage of being easily switched on/off, immediately responding to weather changes and local conditions, such as soil, climate, crops, and farming business models, for precision agriculture.
Funder
U.S. Department of Agriculture
University of Tennessee Institute of Agriculture (UTIA) AgResearch Seed Grant
Reference87 articles.
1. Ammonia and Nitric Acid Demands for Fertilizer Use in 2050;Lim;ACS Energy Lett.,2021
2. How a century of ammonia synthesis changed the world;Erisman;Nat. Geosci.,2008
3. Gielen, D., Bennaceur, K., Kerr, T., Tam, C., Tanaka, K., Taylor, M., and Taylor, P. (2007). Tracking Industrial Energy Efficiency and CO2 Emissions, IEA.
4. A Roadmap to the Ammonia Economy;MacFarlane;Joule,2020
5. Estimation of methane emissions from the U.S. ammonia fertilizer industry using a mobile sensing approach;Zhou;Elem. Sci. Anthr.,2019