Optimal conditions for chlorothalonil and dissolved organic carbon in horizontal subsurface flow constructed wetlands
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The most efficient system of horizontal subsurface flow constructed wetlands (HSSFCW) for removing dissolved organic carbon (DOC) in the presence of chlorothalonil pesticide (CLT) present in synthetic domestic wastewater was determined using the macrophyte Phragmites australis. Two concentrations of CLT (85 and 385 μg L−1) and one concentration of glucose (20 mg L−1) were evaluated in four pilot scale horizontal surface flow constructed wetlands coupled with two sizes of silica gravel, igneous gravel, fine chalky gravel (3.18–6.35 mm), coarse gravel (12.70–25.40 mm) and two water surface heights (20 and 40 cm). For a month, wetlands were acclimated with domestic wastewater. Some groups of bacteria were also identified in the biofilm attached to the gravel. In each treatment periodic samplings were conducted in the influent and effluent. Chlorothalonil was quantified by gas chromatography (GC-ECD m), DOC by an organic carbon analyzer and bacterial groups using conventional microbiology in accordance with Standard Methods. The largest removals of DOC (85.82%25–85.31%25) were found when using fine gravel (3.18–6.35 mm) and the lower layer of water (20 cm). The bacterial groups quantified in the biofilm were total heterotrophic, revivable heterotrophic, Pseudomonas and total coliforms. The results of this study indicate that fine grain gravel (3.18–6.35 mm) and both water levels (20 to 40 cm) can be used in the removal of organic matter and for the treatment of agricultural effluents contaminated with organo-chloride pesticides like CLT in HSSFCW. © 2017 Taylor %26 Francis Group, LLC.
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The most efficient system of horizontal subsurface flow constructed wetlands (HSSFCW) for removing dissolved organic carbon (DOC) in the presence of chlorothalonil pesticide (CLT) present in synthetic domestic wastewater was determined using the macrophyte Phragmites australis. Two concentrations of CLT (85 and 385 μg L−1) and one concentration of glucose (20 mg L−1) were evaluated in four pilot scale horizontal surface flow constructed wetlands coupled with two sizes of silica gravel, igneous gravel, fine chalky gravel (3.18–6.35 mm), coarse gravel (12.70–25.40 mm) and two water surface heights (20 and 40 cm). For a month, wetlands were acclimated with domestic wastewater. Some groups of bacteria were also identified in the biofilm attached to the gravel. In each treatment periodic samplings were conducted in the influent and effluent. Chlorothalonil was quantified by gas chromatography (GC-ECD m), DOC by an organic carbon analyzer and bacterial groups using conventional microbiology in accordance with Standard Methods. The largest removals of DOC (85.82%25–85.31%25) were found when using fine gravel (3.18–6.35 mm) and the lower layer of water (20 cm). The bacterial groups quantified in the biofilm were total heterotrophic, revivable heterotrophic, Pseudomonas and total coliforms. The results of this study indicate that fine grain gravel (3.18–6.35 mm) and both water levels (20 to 40 cm) can be used in the removal of organic matter and for the treatment of agricultural effluents contaminated with organo-chloride pesticides like CLT in HSSFCW. © 2017 Taylor & Francis Group, LLC.
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biofilm; Chlorothalonil; constructed wetlands; dissolved organic carbon; Phragmites australis Bacteria; Biofilms; Chemicals removal (water treatment); Dissolution; Effluent treatment; Gas chromatography; Gravel; Organic carbon; Pesticides; Stream flow; Water levels; Wetlands; Agricultural effluents; Chlorothalonil; Constructed wetlands; Dissolved organic carbon; Domestic wastewater; Horizontal subsurface flow constructed wetlands; Horizontal surfaces; Phragmites australis; Effluents; bacterium; biofilm; chlorothalonil; coliform bacterium; constructed wetland; dissolved organic carbon; domestic waste; grass; macrophyte; pollutant removal; subsurface flow; wastewater treatment; Bacteria (microorganisms); Phragmites australis; Pseudomonas; ammonia; carbon; chlorothalonil; nitrile; phosphate; waste water; biofilm; chemistry; gas chromatography; metabolism; microbial consortium; Poaceae; procedures; sewage; waste water; water management; wetland; Ammonia; Biofilms; Carbon; Chromatography, Gas; Microbial Consortia; Nitriles; Phosphates; Poaceae; Waste Disposal, Fluid; Waste Water; Water Purification; Wetlands
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