Corn Nitrogen Management Influences Nitrous Oxide Emissions in Drained and Undrained Soils

To date, no studies have evaluated nitrous oxide (N2O) emissions of a single versus a split‐nitrogen (N) fertilizer application under different soil drainage conditions for corn (Zea mays L.). The objective of this study was to quantify season‐long cumulative N2O emissions, N use efficiency, and soi...

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Veröffentlicht in:Journal of environmental quality 2016-11, Vol.45 (6), p.1847-1855
Hauptverfasser: Fernández, Fabián G., Venterea, Rodney T., Fabrizzi, Karina P.
Format: Artikel
Sprache:eng
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Zusammenfassung:To date, no studies have evaluated nitrous oxide (N2O) emissions of a single versus a split‐nitrogen (N) fertilizer application under different soil drainage conditions for corn (Zea mays L.). The objective of this study was to quantify season‐long cumulative N2O emissions, N use efficiency, and soil N dynamics when corn received a recommended N rate as single or split‐N application in Minnesota soils with and without tile drainage over two growing seasons. Preplant urea was broadcast incorporated, and in‐season split‐N was broadcast as urea plus urease inhibitor. Tile drainage reduced N2O emissions during periods of excess moisture but did not affect grain yield or other agronomic parameters. Conversely, when precipitation was adequate and well distributed, tile drainage did not affect N2O emissions, but it did enhance grain yield. Averaged across years, the undrained soil emitted 1.8 times more N2O than the drained soil (2.36 vs. 1.29 kg N ha−1). Compared with the Zero‐N control, the Single Preplant and Split N applications emitted 2.1 and 1.6 times more N2O, produced 1.4 and 1.3 times greater grain yield, and resulted in 1.5 and 1.4 times more residual soil total inorganic N, respectively. Per unit of grain yield, the Split application emitted similar amounts of N2O as the Zero‐N control. Averaged across years and drainage, the Split application emitted 26% less N2O than the Single Preplant application (1.84 vs. 2.48 kg N ha−1; P< 0.001) with no grain yield differences. These results highlight that soil drainage can reduce N2O emissions and that a split N application may be a feasible way to achieve N2O reduction while enhancing grain yield. Core Ideas Undrained soils increased N2O emissions relative to drained soils. N fertilization increased N2O emissions regardless of drainage. N2O emissions per unit of grain‐yield were similar for the Split and 0‐N control. Split‐N vs. single application reduced N2O emissions with no impact on grain yield.
ISSN:0047-2425
1537-2537
DOI:10.2134/jeq2016.06.0237