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News Release 16-087

What's good for crops not always good for the environment

Measure of age in soil nitrogen could help precision agriculture

Corn fields in Iowa: Site of NSF's Intensively Managed Landscapes Critical Zone Observatory (CZO).

Corn fields in Iowa: Site of NSF's Intensively Managed Landscapes Critical Zone Observatory (CZO).


July 25, 2016

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What's good for crops is not always good for the environment. Nitrogen, a key nutrient for plants, can cause problems when it leaches into water supplies.

Now, scientists have developed a model to calculate the age of nitrogen in corn and soybean fields, which could lead to improved fertilizer application techniques to promote crop growth while reducing leaching.

Researchers Praveen Kumar and Dong Kook Woo of the University of Illinois published their results today in the journal Water Resources Research, a publication of the American Geophysical Union. The National Science Foundation (NSF) supported the research through its Critical Zone Observatory (CZO) for Intensively Managed Landscapes, one of 10 such NSF CZOs.

"By understanding how long nitrogen stays in the soil and the factors that drive that, we can improve the precision at which we apply nitrogen for agriculture productivity," Kumar said. "We may be able to apply fertilizer specifically in areas that are deficient in nitrogen, in precisely the amount that the plants need to uptake, rather than just applying it uniformly. Potentially, we could see a significant reduction in fertilizer amounts."

Plants take up nitrogen as a nutrient from the soil through their roots. Nitrogen is added to the soil through fertilizer application or by microbes in the soil breaking down organic compounds. However, if the soil contains more nitrogen than the plants need, nitrogen leaches out into the water and can accumulate in lakes, rivers and oceans.

Overdosing the environment

"Nitrogen, usually in the form of nitrate fertilizer, is needed for healthy crop production, but too much is not a good thing, since the excess can contaminate water supplies," said Richard Yuretich, program director in the NSF's Division of Earth Sciences. "Knowing how long nitrate resides in the soil will lead to more efficient agriculture that maximizes plant health without overdosing the environment."

Kumar and Woo developed a numerical model to calculate how long inorganic nitrogen has been in the soil, using a corn-corn-soybean rotation common in the Midwest.

Fresh fertilizer application or microbial production of nitrates and ammonium are considered "age zero" in the numerical model. From there, the researchers compute age by the chemical reactions or transformations nitrogen goes through in the soil, mediated by moisture, temperature and microbes.

Comparing corn and soybeans

The model revealed two surprising findings when comparing the average age of nitrogen in the topsoil with that in deeper layers, and in comparing cornfields with soybean fields.

"The biggest surprise was that we found a lower average age of nitrogen in soybean fields," Woo said. "We use fertilizer on corn, not soybeans. Yet even though we count that fresh fertilizer as age zero, we found a lower average age of nitrogen in soybean fields. We found that is mainly because soybeans uptake the old nitrogen, so the average age is reduced."

When looking at the layers of soil, the researchers initially expected that nitrogen would follow a similar age path to water: newer on top, and growing older as it migrates down through the soil. However, they found that the nitrogen topsoil had a relatively high average age when compared with the water. Looking closer, they realized that one of the forms of nitrogen -- ammonium -- accumulated in the topsoil.

"Ammonium has a positive charge, which adheres to the soil particles and prevents it from leaching to the deeper layers," Woo said. "Because of that, we observe relatively higher nitrogen age in the upper layers, compared with the age of the nitrate that dissolves in water, which doesn't have that barrier and can migrate down through the soil."

Helping farmers use resources wisely

The researchers have established a field site to validate their model by analyzing the composition of nitrogen, oxygen and water in runoff. They hope their work can help farmers more efficiently use resources while also reducing contamination of water sources and downstream habitats.

"The idea of using age for chemical analysis is not new, but no one has studied nitrogen age in the context of an agricultural setting," Kumar said. "By doing that, we are able to reveal patterns of stagnation in the soil, which is different than just using the concentration of nitrogen. The main idea is that there is a better way to apply fertilizer over a landscape than we do presently. We should be looking into more precise approaches."

-NSF-

Media Contacts
Cheryl Dybas, NSF, (703) 292-7734, email: cdybas@nsf.gov
Liz Ahlberg Touchstone, University of Ilinois, (217) 244-1073, email: eahlberg@illinois.edu
Lauren Lipuma, American Geophysical Union, (202) 777-7396, email: llipuma@agu.org

The U.S. National Science Foundation propels the nation forward by advancing fundamental research in all fields of science and engineering. NSF supports research and people by providing facilities, instruments and funding to support their ingenuity and sustain the U.S. as a global leader in research and innovation. With a fiscal year 2023 budget of $9.5 billion, NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and institutions. Each year, NSF receives more than 40,000 competitive proposals and makes about 11,000 new awards. Those awards include support for cooperative research with industry, Arctic and Antarctic research and operations, and U.S. participation in international scientific efforts.

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