Effects of Drainage Water Management in a Corn–Soy Rotation on Soil N2O and CH4 Fluxes

Effects of Drainage Water Management in a Corn–Soy Rotation on Soil N2O and CH4 Fluxes

Drainage water management (DWM), also known as controlled drainage, is a best management practice (BMP) deployed on drainage ditches with demonstrated success at reducing dissolved nitrogen export from agricultural fields. By slowing discharge from agricultural ditches, subsequent anaerobic soil con...

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Bibliographic Details
Published in:Nitrogen (Basel, Switzerland) Vol. 3; no. 1; pp. 128 - 148
Main Authors: Hagedorn, Jacob G., Davidson, Eric A., Fisher, Thomas R., Fox, Rebecca J., Zhu, Qiurui, Gustafson, Anne B., Koontz, Erika, Castro, Mark S., Lewis, James
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-03-2022
Subjects:
Agricultural land
Agricultural practices
Agricultural production
Anaerobic conditions
Best management practices
Controlled drainage
Corn
Crop rotation
Denitrification
Ditches
Drainage
Drainage ditches
Drainage effects
Drainage water
drainage water management
Emission measurements
Emissions
Farm buildings
Farms
Fertilizers
Greenhouse gases
Harvest
Irrigation
Methane
Methanogenesis
Nitrate reduction
Nitrate removal
Nitrates
Nitrogen
Nitrous oxide
Ozone depletion
Precipitation
Rotation
Soil conditions
Soil surfaces
Soils
Soybeans
Statistical analysis
Water management
Water table
United States > US
Maryland
Delmarva Peninsula
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Summary:Drainage water management (DWM), also known as controlled drainage, is a best management practice (BMP) deployed on drainage ditches with demonstrated success at reducing dissolved nitrogen export from agricultural fields. By slowing discharge from agricultural ditches, subsequent anaerobic soil conditions provide an environment for nitrate to be reduced via denitrification. Despite this success, incomplete denitrification might increase nitrous oxide (N2O) emissions and more reducing conditions might increase methanogenesis, resulting in increased methane (CH4) emissions. These two gases, N2O and CH4, are potent greenhouse gases (GHG) and N2O also depletes stratospheric ozone. This potential pollution swapping of nitrate reduction for GHG production could negatively impact the desirability of this BMP. We conducted three years of static chamber measurements of GHG emissions from the soil surface in farm plots with and without DWM in a corn–soybean rotation on the Delmarva Peninsula. We found that DWM raised the water table at the drainage ditch edge, but had no statistically significant effect on water-filled pore space in the field soil surface. Nor did we find a significant effect of DWM on GHG emissions. These findings are encouraging and suggest that, at least for this farm site, DWM can be used to remove nitrate without a significant tradeoff of increased GHG emissions.
ISSN:2504-3129
2504-3129
DOI:10.3390/nitrogen3010010