Abstract
High phosphorus (P) loss from agricultural fields has been an environmental concern because of potential water quality problems in streams and lakes. To better understand the process of P loss and evaluate the effects of different phosphorus fertilization rates on phosphorus losses, the USDA Annualized AGricultural Non-Point Source (AnnAGNPS) pollutant loading model was applied to the Ohio Upper Auglaize watershed, located in the southern portion of the Maumee River Basin. In this study, the AnnAGNPS model was calibrated using USGS monitored data; and then the effects of different phosphorus fertilization rates on phosphorus loadings were assessed. It was found that P loadings increase as fertilization rate increases, and long term higher P application would lead to much higher P loadings to the watershed outlet. The P loadings to the watershed outlet have a dramatic change after some time with higher P application rate. This dramatic change of P loading to the watershed outlet indicates that a “critical point” may exist in the soil at which soil P loss to water changes dramatically. Simulations with different initial soil P contents showed that the higher the initial soil P content is, the less time it takes to reach the “critical point” where P loadings to the watershed outlet increases dramatically. More research needs to be done to understand the processes involved in the transfer of P between the various stable, active and labile states in the soil to ensure that the model simulations are accurate. This finding may be useful in setting up future P application and management guidelines.
Highlights
The impact of high phosphorus (P) losses from watersheds into surface waters can lead to regional and national problems, ranging from the algal blooms and associated water quality problems in LakeErie of the Great Lake systems in Northern Ohio [1], to large areas of hypoxia in the northern Gulf of Mexico [2,3,4,5]
The Annualized AGricultural Non Point Source (AnnAGNPS) Pollutant Loading model is an advanced simulation model developed by the USDA-ARS and NRCS to help evaluate watershed responses to agricultural management practices [18]
AnnAGNPS model was applied to the Ohio Upper Auglaize (UA) watershed to evaluate the impact of P fertilization rates on P loadings and soil P content changes
Summary
The impact of high phosphorus (P) losses from watersheds into surface waters can lead to regional and national problems, ranging from the algal blooms and associated water quality problems in LakeErie of the Great Lake systems in Northern Ohio [1], to large areas of hypoxia in the northern Gulf of Mexico [2,3,4,5]. The impact of high phosphorus (P) losses from watersheds into surface waters can lead to regional and national problems, ranging from the algal blooms and associated water quality problems in Lake. Runoff resulting from agricultural practices has been identified as a primary source of P loads as they are transported into downstream waterbodies [6,7,8,9]. Phosphorus is generally strongly adsorbed by soil. Phosphorus can be dissolved as orthophosphate in the water and transported by surface and subsurface flow [12,15]. It is believed that among multiple sources of P, agricultural runoff from commercial fertilizer applications has the most significant impact on the algae blooms of Lake Erie [17].
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