Effect of pond shape and vegetation heterogeneity on flow and treatment performance of constructed wetlands

Abstract A model framework is developed for nitrogen transformations in a constructed wetland by combining both hydraulics and chemical transformation of nitrogen species. The nitrogen concentration of the effluent water is represented in terms of a convolution between the probability density function of the hydraulic residence times and a chemical transformation function describing the rate of mass-removal of total nitrogen with time in the water as a first-order reaction. Closed-form solutions to the treatment efficiency is derived and related to the nitrogen reduction in wetland Alhagen in Nynashamn, Sweden. Further, the model coefficients are explored by numerical simulations and expressed in terms of heterogeneity of the flow resistance, i.e. in vegetation, and the aspect ratio of the wetland. Heterogeneity in vegetation contributes to increasing the variance of the water residence time and this increases the effluent concentration of nitrogen. Based on the theory and the data from Alhagen, the residence time probability density function for water can have a significant influence on the treatment, and particularly the aspect ratio markedly affects the active water volume and the treatment efficiency.

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