Why nitrous oxide emissions should factor into climate change mitigation


Date:
November 8, 2021
Source:
Iowa State University
Summary:
A newly published study found that a range of agricultural
soils produce nitrous oxide emissions in sufficient quantities
to contribute to climate change. The researchers compared soils
with various moisture content and found agricultural soils are
capable of high nitrous oxide emissions across a wide range of
environmental conditions.



FULL STORY ========================================================================== Poorly drained agricultural soils emit enough of the greenhouse gas
nitrous oxide that the resulting climate change effects could far exceed
the benefits of using the same soils as a means of sequestering carbon, according to a recently published scientific study.


==========================================================================
The study, published Monday in the academic journal Proceedings of the
National Academy of Sciences, found that a range of agricultural soils
produce nitrous oxide emissions in quantities big enough to contribute
to climate change. The researchers compared soils with various moisture
content and found agricultural soils are capable of high nitrous oxide emissions across a wide range of environmental conditions.

Nitrous oxide has 298 times the warming potential of carbon dioxide over
100 years, according to previous research, suggesting that climate change mitigation efforts must account for nitrous oxide, said Steven Hall,
an associate professor of ecology, evolution and organismal biology at
Iowa State University and the study's senior author.

"In this study, we show that the climate warming effects of nitrous oxide emissions from local corn and soybean soils are two-fold greater than
the climate cooling that might be achieved by increasing soil carbon
storage with common agricultural practices," Hall said.

Researchers, farmers and policymakers are considering strategies that
might encourage producers to store carbon, also a greenhouse gas, in the
soil, where it can't contribute to climate change. Hall said storing
carbon in agricultural soils is a valuable tactic to mitigate climate
change, but the new research indicates any such policies should first
take into account nitrous oxide emissions. Failure to do so could result
in policies that are much less effective in addressing climate change.

Instead, Hall said management plans also should encourage nitrous oxide mitigation strategies in concert with carbon sequestration. Examples
of such strategies include more precise and efficient use of nitrogen fertilizer. New products known as enhanced efficiency fertilizers, as
well as the application of biochar to fields, might also help to limit
nitrous oxide emissions.

Microorganisms in the soil give off nitrous oxide as a byproduct as they
cycle nitrogen. Nitrogen stimulates nitrous oxide production, so adding nitrogen fertilizers to soil tends to result in more emissions.

"If we want to maximize our climate benefit, we want to be strategic about
it," Hall said. "We're not simply going to flip the switch on climate
just by putting more carbon in the soil. Nitrous oxide emissions need
to be a priority as well." Hall and his fellow researchers developed
a new means of measuring nitrous oxide emissions from corn and soybean
fields to help gather data for the study.

The scientists tweaked previously existing technologies to measure
nitrous oxide emissions every four hours. The technology utilizes
small containers placed at various locations on top of the soil of ISU
research farms in central Iowa. The containers pump air samples into
a central shed where an analyzer automatically measures nitrous oxide
content. This method hadn't been used before to measure nitrous oxide,
and Hall said the researchers had to design the system to withstand the
wet conditions often present in agricultural fields.

Hall's coauthors include Nathaniel Lawrence, an ISU graduate student in ecology, evolution and organismal biology; Carlos Tenesaca, a research scientist in ecology, evolution and organismal biology; and Andy
VanLoocke, an associate professor of agronomy.

========================================================================== Story Source: Materials provided by Iowa_State_University. Note: Content
may be edited for style and length.


========================================================================== Journal Reference:
1. Nathaniel C. Lawrence, Carlos G. Tenesaca, Andy VanLoocke, Steven J.

Hall. Nitrous oxide emissions from agricultural soils challenge
climate sustainability in the US Corn Belt. Proceedings of the
National Academy of Sciences, 2021; 118 (46): e2112108118 DOI:
10.1073/pnas.2112108118 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2021/11/211108161422.htm

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