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ARS Home » Southeast Area » Florence, South Carolina » Coastal Plain Soil, Water and Plant Conservation Research » Research » Publications at this Location » Publication #399422

Research Project: Innovative Manure Treatment Technologies and Enhanced Soil Health for Agricultural Systems of the Southeastern Coastal Plain

Location: Coastal Plain Soil, Water and Plant Conservation Research

Title: Long-term nitrogen and phosphorus outflow from an instream constructed wetland under precipitation variability

Author
item Sohoulande, Clement
item Szogi, Ariel
item NOVAK, JEFFERY - Retired ARS Employee
item Stone, Kenneth
item Martin, Jerry
item Watts, Donald - Don

Submitted to: Sustainability
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 12/7/2022
Publication Date: 12/9/2022
Citation: Sohoulande Djebou, D.C., Szogi, A.A., Novak, J., Stone, K.C., Martin, J.H., Watts, D.W. 2022. Long-term nitrogen and phosphorus outflow from an instream constructed wetland under precipitation variability. Sustainability. https://doi.org/10.3390/su142416500.
DOI: https://doi.org/10.3390/su142416500

Interpretive Summary: In many agricultural watersheds, surface runoff often causes unwanted nitrogen (N) and phosphorus (P) losses from croplands into surface water bodies. When this phenomenon is pronounced, it significantly changes N and P concentrations in water bodies affecting aquatic ecosystems. To protect water bodies from contamination, the installation of instream constructed wetlands (ICWs) is often reported as a low-cost alternative to conventional water treatment systems. Indeed, ICWs have the capacity to collect and temporarily retain nutrients transported from agricultural landscapes then slowly release them into surface water bodies. However, the long-term behavior of ICWs relative to N and P outflow control is still not enough reported. Especially in the context of climate change, it is relevant to investigate the effect of precipitation variability on ICWs N and P outflow. This study uses the soil and water assessment tool (SWAT) model to approximate the long-term behavior of an ICW installed in a small agricultural watershed. The model was set assuming a continuous corn and soybean rotation on croplands, then 2001-2020 simulation was used to evaluate the implication of precipitation variability on nutrient outflows. Results show meaningful changes in the precipitation pattern with contrasting effects on N and P outflows. While analyses show significant trends in the maximum monthly precipitation, nutrient outflows during two consecutive decades, 2001-2010 and 2011-2020, show an increase of 46% for total N, and 82% for total P. The increase of nutrient outflow is particularly pronounced for total P and dissolved P which show significant trends and high correlations with maximum monthly precipitation. An exception is nitrate-N outflow, which counts on average for less than 5% of total N outflow but appears more affected by the timing of N fertilization in the watershed.

Technical Abstract: In many agricultural watersheds, surface runoff often causes unwanted nitrogen (N) and phosphorus (P) losses from croplands into stream networks. When this phenomenon is pronounced, it significantly changes N and P concentrations in streams affecting aquatic ecosystems. To protect stream water quality, the installation of instream constructed wetlands (ICWs) for treating runoff water is often reported as a low-cost alternative to conventional water treatment systems. Indeed, ICWs have the capacity to collect and temporarily retain nutrients transported from agricultural landscapes then slowly release them into downstream networks. However, the long-term hydrologic behavior of ICWs relative to N and P outflow control is still insufficiently reported. Especially in the context of climate change, it is relevant to investigate the effect of precipitation variability on ICWs N and P outflow. This study uses the soil and water assessment tool (SWAT) model to approximate the long-term hydrologic behavior of an experimental ICW installed in a small agricultural watershed. The model was set assuming a continuous corn and soybean rotation on croplands, then a multidecadal (period 2001-2020) simulation was used to evaluate the implication of precipitation variability on total nitrogen (TN), nitrate-N (NO3-N), total P (TP), and dissolved P (DP) outflows. Results show meaningful changes in the precipitation pattern with contrasting effects on N and P outflows. While analyses show significant trends in the maximum monthly precipitation, nutrient outflows during two consecutive decades, 2001-2010 and 2011-2020, show an increase of 46% for TN, and 82% for TP. The increase of nutrient outflow is particularly pronounced for TP and DP which show significant trends and higher correlations with maximum monthly precipitation. An exception is nitrate-N outflow, which counts on average for less than 5% of TN outflow but appears more affected by the timing of N fertilization in the watershed.