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Residuals and Manure Management for Environmental and Agronomic Benefits. Olawale O. Oladeji Soil and Water Science Department University of Florida. Residual Application Rates. Meet N needs of plants (N-based) and avoid excessive N that can pollute the ground water.
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Residuals and Manure Management for Environmental and Agronomic Benefits Olawale O. Oladeji Soil and Water Science Department University of Florida
Residual Application Rates • Meet N needs of plants (N-based) and avoid excessive N that can pollute the ground water. • N-based rates often provide and load soils with excessive P • Excess P: • Not harmful to plants • Potential environmental impact
Phosphorus Loss • Sandy soils of Florida sorb P poorly and surround P sensitive water bodies
Water Treatment Residuals (WTRs) • Generated with Al and Fe coagulants • Mostly Al and Fe hydroxides • High affinity for phosphorus !!!
WTR Rates • Land application of WTRs could lead to excessive immobilization of soil P and Al toxicity • Negative impact of WTRs calls for best management for environmental and agronomic benefits Inadequate WTR Excess WTR Deficiency (P loss) Deficiency (Excessive immobilization)
Soil Test Methods • A good soil test could be a tool to identify environmental and agronomic thresholds to arrive at optimum rates of WTRs and P sources. • Conflicting results from the use of conventional soil test methods (e.g., Mehlich 1) in studying soils receiving WTR call for identifying suitable soil test methods.
Hypotheses • There exist suitable soil test methods for P bioavailability in soil receiving organic sources of P and WTRs. • (1) P-based rates of different organic sources of P without WTR optimize P uptake. (2) N-based rates of different organic sources of P with WTR optimize P uptakes. • Amendment rates selected in (II) that optimize P uptake also minimize leaching and runoff P.
Objectives • Determine suitable soil test methods for P bioavailability in soils amended with different P sources and WTR. • Determine the rates of WTR and organic P sources that optimize plant P uptake while minimizing environmental P hazards. • Evaluate the impacts of selected amendments rates (WTR and organic P sources) on leaching and runoff P. • Validate the expected impacts of selected amendment (WTR and organic P sources) rates on P uptake and P loss in field settings.
Objectives: Determine suitable soil test methods for P bioavailability in soil treated with different organic sources of P in the presence and absence of WTR Determine the rates of organic sources of P (amendments), with and without WTR, that optimize P uptake Design: 4X2X3 factorial experiment plus 1 control in randomized complete block with 3 replicates Factors: 4 P Sources (Poultry manure, Boca Raton Biosolids, Pompano Biosolids, TSP) 2 P Sources rates (N- and P-based) 3 WTRs rates (0, 1.0 and 2.5% oven dry basis) Test plants: Bahiagrass (Paspalumnotatum Fluggae) follow by Fescue grass (Festucaovina “Glauca”) Experiment I: Glasshouse Study
Glasshouse Experiment Data to be collected: • Total P and soil test P (using selected extraction methods: Mehlich-1, Water extractable P, Fe strip P) • Plant dry matter yield. • Plant P content and uptake.
Experiment II: Rainfall Simulation Objectives: • Evaluate impact of organic sources of P on leaching and runoff P • Determine the effect of WTR placement on leaching and runoff P • Determine the environmental threshold for P Design: 4X2X2X2 factorial experiment plus 1 control in randomized complete block with 3 replicates Factors: • 4 P Sources: Poultry manure, Boca Biosolids, Pompano Biosolids, TSP • 2 P Sources rates :N- and P-based • 2 WTRs rates : 0, and 1.0% • 2 placement methods: Surface and Mixed
Rainfall Simulation • Runoff boxes (100cm*20cm*7.5cm) • Surface slope (3 degree) • Simulated rain 7.1cm hr-1 • Three rain events at 2-days interval • Runoff collected for 30 minutes (Leachate also collected) Rainfall Simulator
Rainfall Simulation Data to be collected: • Quantity of runoff and leachate • Total runoff and leaching P • Runoff and leaching dissolved P
Expected Results • N based rates with WTR and P based rates expected to give soil test P (STP) below the change point (environmental threshold) • N based rate without WTR is expected to give STP and RDP above the change point • Environmental threshold STP is expected to be about three times agronomic optimum Environmental threshold Agronomic threshold RDP (mgL-1) Change point A E = ~3A Soil test P
Experiment III: Field Experiment Field validation of impacts of selected rates and sources of P and WTR on P loss and uptake Design: 4X2X3 factorial experiment plus 1 control in randomized complete block with 3 replicates Factors: • 4 P Sources: Poultry manure, Boca Biosolids, Pompano Biosolids, TSP • 2 P Sources rates :N- and P-based • 2 WTRs rates (0, and 1.0%) Test plant: Bahiagrass
Field Experiment Data to be collected: • Runoff and leaching P • Plant dry matter yield • Plant P uptake • Total P and soil test P using selected extraction methods (Mehlich-1, Water extractable P, Fe strip P); oxalate extractable P, Al, Fe,).
Preliminary Results • WEP and ISP are better correlated with P uptake than Mehlich-1 • WEP and ISP are potential soil tests for P in WTR treated soils.
Preliminary Results • Potential P loss (readily desorbable P) is lower in WTR treated soil as indicated by the WEP and ISP With WTR Without WTR
Preliminary Results • DPSox = (Ox-P) X 100 • α(Ox-Fe + Ox-Al)
Preliminary Results Nair et al., 2004 • Treatments without WTR have %DPSox above the change point. • Treatment with WTR have %DPSox below the change point (environmental threshold). calculated using oxalate extraction (DPSox) for soil receiving different P sources with and without WTR. 35 30 20 25 15 With WTR WEP (mg/kg) 10 Control 5 Without WTR 0 0 20 40 60 80 100 120 %DSP(OX)
Impact of WTR on Soil and Plants • WTR addition lowers DPSox without significantly impacting the plant