Everglades Research and Education Center, Belle Glade, FL ......Everglades Research and Education...
Transcript of Everglades Research and Education Center, Belle Glade, FL ......Everglades Research and Education...
Impact of Suppression of Floating Aquatic Vegetation on Canal Sediment Properties in South Florida
Anne E. Sexton ([email protected]), Jehangir H. Bhadha, Timothy A. Lang, and Samira H. Daroub Everglades Research and Education Center, Belle Glade, FL and Soil and Water Science Department, Gainesville, FL
Introduction Floating aquatic vegetation (FAV) has a significant impact on the ability of agricultural canal sediment to retain and release phosphorus (P) in the Everglades Agricultural Area (EAA) in South Florida.
Hypotheses: • Suppressing FAV will reduce the labile P in canal sediments. • Sediments discharged during drainage events will be higher in total P
than sediments in the canals.
Objectives: • Compare amount and forms of P in farm canals with and without FAV. • Compare amount and forms of P in farm canal sediment and sediment
discharged during farm drainage.
Treatment farms used spot-spraying of herbicide to maintain <25% FAV coverage, while control farms practiced normal canal management.
Methods
Sequential P-Fractionation
• Phosphorus with varying rates of bioavailability are present in sediments (Figure 6; Reddy et al., 1998).
• P-fractionation selectively extracts and measures the amount of labile and recalcitrant-P forms in sediment.
• Discharged particulates were higher in organic matter and TP than canal SED, and labile P was higher in discharged sediment than canal SED because the floc detrital matter high in P was easily transported with the drainage water.
• Between SED T/C, farms suppressing FAV had lower TP than control farms possibly because the FAV were storing P that would otherwise be incorporated deeper into the canal sediments.
• The positive trend seen in the water TP concentration with increased FAV coverage supports the idea that FAV are storing P that would otherwise be taken out of the water column and incorporated deeper in canal sediments. As FAV cover increases and peaks, PP follows as higher amounts of detrital matter are deposited.
Discussion
Reddy, K. R., Wang, Y., DeBusk, W. F., Fisher, M. M., & Newman, S. (1998). Forms of Soil Phosphorus in Selected Hydrologic Units of the Florida Everglades. Soil Science Society of America Journal, 62, 1134-1147.
The experimental design of FAV effects on canal functions compared complete FAV coverage to no coverage (figure 3). With full coverage (left), sunlight and gas exchange is impeded, and there is an increase in floc sediment generation and loss during water movement as compared to clear canal (right).
Table 1: Experimental farm pairs (1, 2, 3, and 4), treatment (T) and control (C) assignment, farm size (acres), and percent land cover by crop type (dominant crop bolded).
Farm
ID
Farm
Pair
Size
(acres) Crop type
Farm
ID
Farm
Pair
Size
(acres) Crop type
3102
(T) 1
1387 Sugarcane,
vegetables
6117
(T) 3
781 Sugarcane,
sweet corn
3103
(C) 609
Sugarcane,
vegetables, rice
1813
(C) 594
Sugarcane,
sweet corn
0401
(T) 2
908 Sugarcane,
sweet corn
4701
(T) 4
630 Sugarcane,
rice and fallow
2501
(C) 824
Sugarcane,
sweet corn
4702
(C) 640
Sugarcane,
rice
Farm Locations and Descriptions
Sediment Sampling Core samples were collected from transects A, B, and C (figure 5) twice per year, with the top 5 cm sectioned for analysis. Drainage waters were settled during pumping events to collect discharged particulate matter sediment (PM).
Discharged waters were collected during drainage events at each farm’s pump station and analyzed for TP, particulate P (PP), and soluble reactive P (SRP). Percent FAV coverage determined biweekly.
Water Quality Results
This project is funded by the Everglades Agricultural Area Environmental Protection District, and is overseen by the South Florida Water Management District accordance with the Everglades Forever Act (1994).
Acknowledgements
References
Sediment Phosphorus Results
Key Findings
• Particulate Matter TP and organic matter significantly higher than SED (table 2);
• Control SED higher in TP than Treatment SED;
• Treatment PM samples higher in TP than Control PM;
• No significant differences in pH.
Table 2: Sediment and Particulate Matter Properties Mean Values and Level of Significance
Source of Variation
Total Phosphorus
(mg/kg)
Organic Matter
(%) pH
Canal Sediment/Particulate Matter Discharged (SED/PM)
Canal Sediment 1022a** 39a*** 7.35a
PM Sediment 2064b** 50b*** 7.19a
Treatment/Control (T/C)
Treatment 1538a 47a 7.28a Control 1022b 39a 7.35a
SED/PM* T/C
SED, Treatment 947a*** 40a 7.36a
SED, Control 1069b*** 39a 7.35a
PM, Control 1733c*** 47a 7.17a
PM, Treatment 2129d*** 53a 7.20a a, b, c representing LSMeans Tukey HSD
*,**,*** indicate P < 0.05, 0.01, 0.001 respectively
There is support that drainage water sediment is higher in TP when FAV is not suppressed, but there was no support that FAV suppression reduces labile P in canal sediments compared to normal management. Phosphorus in drainage water tended to increase with increased FAV coverage. Higher amounts of TP, labile P, and organic matter in discharged sediment may be due to large amounts of floccy sediment and detrital matter generated by FAV being carried out during drainage.
Conclusions
The study area is within the larger Everglades ecosystem of South Florida (figure 4). The experiment included four treatment-control farm pairs within the EAA (red box) dominated by sugarcane farming (table 1).
Discharged PM labile P was significantly higher than all SED (Figure 7) when treatment and control samples combined.
Common canal conditions in the EAA allow FAV infestations up to complete coverage before mass herbicide application (figure 1).
Canals clear of FAV (figure 2) were tested as to their ability to retain P in this experiment.
Particulate matter and sediment (SED) samples were analyzed for total P (TP), percent organic matter, pH, and P fractionation from 2011-2016.
No significant difference in labile P between SED treatment and control (Figure 8). Treatment and control PM higher than SED.
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Averaged Phosphorus Fractionation of Sediment vs. Particulate Matter
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Averaged Phosphorus Fractionation of Sediment vs. Particulate Matter by Treatment-Control
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Total P, PP, and SRP in both the control and treatment farms increased after percent FAV peaked (figures 9 and 10).
The control farm (figure 10) had no FAV suppression and as the percent coverage increased over time, TP and PP increased as well. Particulate P was consistently higher than SRP in the control farm (figure 10), but varied in the treatment farm (figure 9).
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Phosphorus Fractionation Results