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United States Department of Agriculture

Agricultural Research Service

Research Project: FARMING PRACTICES FOR THE NORTHERN CORN BELT TO PROTECT SOIL RESOURCES, SUPPORT BIOFUEL PRODUCTION AND REDUCE GLOBAL WARMING POTENTIAL

Location: Soil and Water Management Research

Title: The Effect of Elevated CO2 and O3 on Soil Nitrogen Inputs and Losses in a Soybean Agroecosystem in Illinois

Authors
item Decock, Charlotte -
item Chung, Haegeun -
item Venterea, Rodney
item Six, Johan -

Submitted to: ASA-CSSA-SSSA Annual Meeting Abstracts
Publication Type: Abstract Only
Publication Acceptance Date: May 1, 2010
Publication Date: October 31, 2010
Citation: Decock, C., Chung, H., Venterea, R.T., Six, J. 2010. The Effect of Elevated CO2 and O3 on Soil Nitrogen Inputs and Losses in a Soybean Agroecosystem in Illinois [abstract]. ASA-CSSA-SSSA Annual Meeting Abstracts. Paper No. 592.

Technical Abstract: It has been found that elevated atmospheric carbon dioxide (eCO2) and tropospheric ozone (eO3) affect belowground microbial processes, including N transformations, through plant-mediated changes. Conversely, changes in soil organic carbon sequestration and plant biomass production are constrained by N availability. Furthermore, changes in N losses to the groundwater or the atmosphere cause eutrophication of aquatic ecosystems and global climate change, respectively. Therefore, it is pertinent to assess the effect of eCO2 and eO3 on N inputs and losses. In a soybean agroecosystem in Illinois, we used natural abundance stable isotopes as a proxy to integrate long-term N inputs and losses, based on minimal isotopic discrimination during biological N2-fixation, and 15N depletion associated with lost N. Our isotopic model suggested that N-inputs and losses decreased by eCO2, whereas inputs and losses increased by eO3. Under eCO2, changes in inputs and losses balanced each other out, while a larger increase in inputs compared to losses under eO3 resulted in a larger soil N content under eO3 compared to ambient. Differences in N-losses between treatments are due to removal of soil derived N by harvest, N leaching and gaseous N emissions. Soil derived N removed by harvest was increased by eCO2, and there was a stimulation of the cumulative N2O flux during the growing season in 2005 but not in 2006. Consequently, the reduction in N loss under eCO2 compared to ambient must be a result of decreased N leaching or decreased total gaseous loss. eO3 did not affect the amount of soil N removed by harvest or the cumulative N2O flux during the growing season. Hence, the increased N loss under eO3 compared to ambient might be due to changes in total gaseous N loss, N2O emissions during the non-growing season or increased leaching. In conclusion, our results warn for increased environmental risk for hazardous N loss from agroecosystems under changing atmospheric conditions.

Last Modified: 9/22/2014
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