ASSESSING WATER AND SEDIMENT CONTROL BASINS (WASCoBs) IN SOUTHEN ILLINOIS: INFLUENCE ON WATER QUAILITY, LEGACY PHOSPHORUS, AND SEDIMENT TRAPPING

Mertz, Sierra Victoria

01 August 2024

Best Management Practices (BMPs) are conservation practices designed by Natural Resource Conservation Service to help mitigate erosion and nutrient losses in agriculture. Water and Sediment Control Basins (WASCoBs) are BMPs implemented in agriculture fields with sloping topography that are susceptible to erosion to help reduce sediment and nutrient losses. There is little research examining the water quality impacts of WASCoBs and their ability to decrease nutrients in water runoff. Runoff samples were collected following intense rain events in seven basins and analyzed for total suspended soils (TSS), total phosphorus, dissolved reactive phosphorus (DRP), ammonium-nitrogen, and nitrate-nitrogen. Nutrient and sediment concentrations and discharge measurements were used to determine event loads for each basin. The WASCoBs trapped an average of 63.4% of TSS, 30.5% of total phosphorus, 15.3% of DRP, 21.8% of ammonium-nitrogen, and 62.9% of nitrate-nitrogen. An Unmanned Aerial Vehicle (UAV) was used to estimate sedimentation rates and proved to be less effective for annual sediment estimates, but perhaps more accurate on a multi-year basis. A detailed soil assessment was performed on all thirty-two basins to estimate short-term legacy phosphorus accumulation. The thirty-two basins trapped an average of 5,403.0 kg/ha of sediment and 16.8 kg/ha of phosphorus. An average of 22 mg kg-1 of total phosphorus accumulated across the basins in one year of sediment accumulation. Potential crop yield penalty was investigated to see the impact between inside the basins compared to the surrounding area. Corn had a decrease of 5.1% yield and soybeans had a decrease of 36.9% in yield inside the basins.

legacy phosphorus

soil erosion

water and sediment control basins

water quality

Residual Soil Phosphorus in Tropical Oxisols: An Opportunity to Enhance Fertilizer Use Efficiency?

Bomeisl, Lauren

01 January 2019

Phosphorus (P) is essential to life on Earth and often the limiting nutrient in agricultural systems. P fertilizer is thus an essential resource to maintain food security. In the last half century, agricultural intensification has led to an increase in P fertilizer consumption from 4.6 to 17.5 Tg of P/year to meet rising global food demand. Mineral P (i.e., phosphate rock) is a non-renewable resource in the context of the Anthropocene, and its price is vulnerable to global market fluctuations. Increased efficiency of P use on farms is considered the most effective strategy to conserve P. The soybean industry demands 9.7% of global P use, of which Brazil’s soy industry consumes the most, accounting for 5.8% of the world’s P2O5 use in 2014. This global source of soy production is challenged by the unique tendency of weathered tropical soils, such as Oxisols, to retain (i.e., fix) P in forms that are unavailable to crops. The accumulation of soil P due to years of P fertilization in excess of harvested P is referred to as “residual” or “legacy” P. Historical hotspots for crop production in the US and Europe have relied on residual soil P stocks to maintain yields despite reduced P inputs. Whether Brazil will be able to utilize the same strategy depends on the accessibility of residual soil P stocks when applied fertilizer P is reduced. Field research on this topic remains relatively scarce for cultivated Oxisols in tropical climates. I conducted a field trial at Tanguro Ranch in Mato Grosso, Brazil on a field that has been fertilized at standard high rates for 10 years to test whether residual soil P can be accessed by soy crops. Soy yield response differed significantly (p < 0.05) based on the interaction between fertilization treatment (0%, 50%, or 100% of standard P fertilization) and soil texture. My results highlight opportunities to enhance P fertilizer use efficiency in intensive tropical agriculture.

Amazon

fertilizer

Legacy Phosphorus

Mato Grosso

Residual Phosphorus

soil fertility

Agriculture

Soil Science

Evaluating the Impacts of Climate and Stacked Conservation Practices on Nutrient Loss from Legacy Phosphorus Agricultural Fields

Crow, Rachelle Leah

09 August 2022

No description available.

Agricultural Engineering

Nutrients

Phosphorus

Legacy Phosphorus

Climate

Stacked Practices

Wetland

Best Management Practices

Evaluating the Effects of Legacy Phosphorus on Dissolved Reactive Phosphorus Losses in Tile-Drained Systems

Pauline Kageha Welikhe (8803301)

07 May 2020

<p>Eutrophication due to phosphorus (P) enrichment continues to be a primary water quality concern affecting freshwater and marine estuaries around the world. Excessive anthropogenic P inputs, driven by the need to meet the rising food and energy demands of a growing and increasingly urbanized population, have resulted in the buildup of P creating legacy (historical) P pools in agricultural landscapes. There is growing evidence that remobilization of accumulated legacy P can interfere with conservation efforts aimed at curbing eutrophication and improving water quality. Less is known about the magnitude and effects of these legacy P pools on dissolved reactive P (DRP) losses in tile-drained systems. This dissertation consists of three separate inquiries into how legacy P may affect DRP losses in tile drains. In the first inquiry, we examined the possibility of developing a suitable pedo-transfer function (pedoTF) for estimating P sorption capacity (PSC). Subsequent PSC-based indices (Phosphorus Saturation Ratio (PSR) and Soil Phosphorus Storage Capacity (SPSC)) were evaluated using daily water quality data from an in-field laboratory. The pedoTF derived from soil aluminum and organic matter accurately predicted PSC (R² = 0.60). Segmented-line models fit between PSR and soluble P (SP) concentrations in both desorption assays (R² = 0.69) and drainflows (R² = 0.66) revealed apparent PSR thresholds in close agreement at 0.21 and 0.24, respectively. Linear relationships were observed between negative SPSC values and increasing SP concentrations (R² = 0.52 and R² =0.53 respectively), and positive SPSC values were associated with very low SP concentrations in both desorption assays and drainflows. Zero SPSC was suggested as a possible environmental threshold. Thus, PSC-based indices determined using a pedoTF could estimate the potential for SP loss in tile drains. Also, both index thresholds coincided with the critical soil test P level for agronomic P sufficiency (22 mg kg^-1 Mehlich 3 P) suggesting that the agronomic threshold could serve as an environmental P threshold. In the second inquiry, PSC- based indices in addition to other site characteristics present in a P index (PI), were used as inputs in the development of a multi-layer feed-forward artificial neural network (MLF-ANN). The MLF-ANN was trained, tested, and validated to evaluate its performance in predicting SP loss in tile drains. Garson’s algorithm was used to determine the weight of each site characteristic. To assess the performance of ANN-generated weights, empirical data from an in-field laboratory was used to evaluate the performance of an unweighted PI (PI_NO), a PI weighted using Lemunyon and Gilbert weights (PI_LG), and an ANN-weighted PI (PI_ANN) in estimating SP losses in tile effluent. The MLF-ANN provided reliable predictions of SP concentrations in tile effluent (R² = 0.99; RMSE = 0.0024). Soil test P, inorganic fertilizer application rate (FPR), SPSC, PSR, and organic P fertilizer application rate (OPR), with weights of 0.279, 0.233, 0.231, 0.097, and 0.084, respectively, were identified as the top five site characteristics with the highest weights explaining SP loss in tile discharge. These results highlighted the great contribution of both contemporary and legacy P sources to SP concentrations in tile discharge. Also, PI_ANNwas the only PI with a significant exponential relationship with measured annual SP concentrations (R²= 0.60; p < 0.001). These findings demonstrated that MLF-ANNs coupled with Garson’s algorithm, can accurately quantify weights for individual site characteristics and develop PIs with a strong correlation with measured SP in tile discharge. Finally, in the third inquiry, we compared DRP loads and flow-weighted mean DRP (FDRP) concentrations in P source and P sink soils and evaluated the predominant DRP concentration – discharge (C-Q) behavior in these soils on a daily and event scale. At the daily scale, C-Q patterns were linked to the soil P status whereby a chemostatic and dilution behavior was observed for P source and P sink soils, respectively. At the event scale, C-Q patterns were linked to soil P status, flow path connectivity, and mixing of event water, matrix water, and rising shallow groundwater. The predominant anti-clockwise rotational pattern observed on P source soils suggested that, as the discharge event progressed, contributions from P poor waters including matrix and shallow groundwater resulted in lower DRP concentrations on the rising limb compared to the falling limb. However, the variable flushing and dilution behavior observed on the rising limb suggested that, in addition to discharge and soil P status, rapid exchanges between P pools, the magnitude of discharge events (Q), and the relative number of days to discharge peak (D_rel) also regulated DRP delivery. On the other hand, the predominant non-hysteretic C-Q behavior in P sink soils suggest that DRP loss from these soils can be discounted. Our collective results highlight the need for nutrient and conservation practices focused on P drawdown, P sequestration, and P supply close to the crop needs, which will likely be required to convert P sources to sinks and to avoid the conversion of P sinks to sources. </p>

Environmental Science

Environmental Management

Agricultural Land Management

Legacy phosphorus

Dissolved reactive phosphorus

Tile-drained systems

Phosphorus management

Water quality

Evaluating the Advective Capacity of Regional Groundwater Flow Regimes to Transport Legacy DRP in a Tiled Farm Field of The Maumee River Watershed

McCormick, Matthew Ryan

January 2021

No description available.

Environmental Geology

Environmental Science

Geology

Hydrology

Hydrologic Sciences

Water Resource Management

Agricultural Chemicals