This report describes investigations using artificial wetlands which quantitatively assess the ro... more This report describes investigations using artificial wetlands which quantitatively assess the role of each of three higher aquatic plant types, Scirpus validus (bulrush), Phragmites communis (common reed) and Typha lalifola (cattail), in the removal of nitrogen (via sequential nitrification-denitrification), BOD and TSS from primary municipal wastewaters. During the period August 1983-December 1984, the mean ammonia concentration of 24.7mgl-' in the primary wastewater inflow (hydraulic application rate = 4.7 cm day-') was reduced to mean effluent levels of 1.4 mg 1-' for the bulrush bed, 5.3 mg1-I for the reed bed and 17.7mg1-I for the cattail bed, as compared to a mean value of 22.1 mgl-I for the unvegetated (control) bed. For all three vegetated beds, the mean effluent ammonia values were significantly below that for the unvegetated bed and for the inflow. The bulrushes and reeds (in that order) proved to be superior at removing ammonia, both with mean effluent levels significantly below that for the cattail bed. The high ammonia-N (and total N) removal efficiencies shown by the bulrush and reed beds are attributed to the ability of these plants to translocate 0, from the shoots to the roots. The oxidized rhizosphere so formed stimulates sequential nitrification-denitrification. Similarly BOD removal efficiencies were highest in the bulrush and reed beds, both with mean effluent BOD levels (5.3 and 22.2 mg I-', respectively) significantly below that for the unvegetated bed (36.4 mg I-') and equal to or better than secondary treatment quality (30 mg I-'). Our results demonstrate that higher aquatic plants can indeed play a significant role in secondary and advanced (N removal) wastewater treatment by wetland systems, a role that is completely distinct from that associated with their pollutant uptake capacity.
This report describes investigations using artificial wetlands which quantitatively assess the ro... more This report describes investigations using artificial wetlands which quantitatively assess the role of each of three higher aquatic plant types, Scirpus validus (bulrush), Phragmites communis (common reed) and Typha lalifola (cattail), in the removal of nitrogen (via sequential nitrification-denitrification), BOD and TSS from primary municipal wastewaters. During the period August 1983-December 1984, the mean ammonia concentration of 24.7mgl-' in the primary wastewater inflow (hydraulic application rate = 4.7 cm day-') was reduced to mean effluent levels of 1.4 mg 1-' for the bulrush bed, 5.3 mg1-I for the reed bed and 17.7mg1-I for the cattail bed, as compared to a mean value of 22.1 mgl-I for the unvegetated (control) bed. For all three vegetated beds, the mean effluent ammonia values were significantly below that for the unvegetated bed and for the inflow. The bulrushes and reeds (in that order) proved to be superior at removing ammonia, both with mean effluent levels significantly below that for the cattail bed. The high ammonia-N (and total N) removal efficiencies shown by the bulrush and reed beds are attributed to the ability of these plants to translocate 0, from the shoots to the roots. The oxidized rhizosphere so formed stimulates sequential nitrification-denitrification. Similarly BOD removal efficiencies were highest in the bulrush and reed beds, both with mean effluent BOD levels (5.3 and 22.2 mg I-', respectively) significantly below that for the unvegetated bed (36.4 mg I-') and equal to or better than secondary treatment quality (30 mg I-'). Our results demonstrate that higher aquatic plants can indeed play a significant role in secondary and advanced (N removal) wastewater treatment by wetland systems, a role that is completely distinct from that associated with their pollutant uptake capacity.
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