Modelling phosphorus dynamics in constructed wetlands upgraded with reactive filter media

LICENTIATE THESIS IN LAND AND WATER RESOURCES ENGINEERING

STOCKHOLM, SWEDEN 2017

Modelling phosphorus dynamics in

constructed wetlands upgraded with

reactive filter media

RAJABU HAMISI

Academic Dissertation which, with due permission of the KTH Royal Institute of Technology, is submitted for public defence for the Degree of Licentiate of Engineering on Monday the 12th June 2017, at 1:00 p.m. in V1, Teknikringen 76, KTH, STOCKHOLM.

KTH ROYAL INSTITUTE OF TECHNOLOGY

SCHOOL OF ARCHITECTURE AND THE BUILT ENVIRONMENT (ABE)

Abstract

Mechanisms underlying the process of phosphorus mobility and retention were evaluated using the SWAT model at a catchment scale and 3D Reactive TRransPort model (RETRAP – 3D) for phosphorus removal in the COMSOL Multiphysics. The aims of the thesis were to: i) improve understanding of phosphorus mobility in the Oxundaån catchment; ii) identify suitable sites for constructing wetlands; iii) develop the numerical reactive transport model in order to identify key parameters which affects sorption efficiencies of the reactive adsorbent media; iv) predict the media's sorption efficiencies; and v) evaluate the viable reactive adsorbent media for mitigating eutrophication in the Baltic Sea. To predict phosphorus removal efficiencies of the adsorbent media and visualize the sorption process within the constructed wetlands, a three-dimensional model was developed within the COMSOL Multiphysics^®. The reactive transport model was developed by coupling four physics interfaces to simulate the processes of water flow dynamics, transport of diluted phosphorus species, reaction kinetics and heat transfer in the porous media. The SWAT modelling results showed that arable land with the less background phosphorus retention, lower soil permeability and lower land slope could provide suitable sites for constructing wetlands. The simulated phosphorus sorption efficiency of the reactive filter media was ranked: 88 % (113 gP kg^-1) for Polonite^®, 85 % (81gP kg^-1) for Filtralite P^®, 62 % (61 gPkg^-1) for Blast furnace slag, 57 % (44gP kg^-1) for Wollastonite. In comparison to other media, Polonite^® was observed to be a suitable reactive adsorbent media for wetland applications under different hydraulic loading rates and pH change, whose P-removal efficiency last for six years. The modelling results showed less significant effects of particle size on the phosphorus removal efficiency as compared to solution pH and Ca mineral content. Precipitation was identified to be the dominant mechanisms for phosphorus removal in these media with the positive correlation to increase of pH and Calcium content. The satisfactory agreements observed between the simulated outputs and experimental data accurately captured the processes of phosphorus mobility and removal. The results suggest that the reactive transport models are valuable tools for providing insight into sorption processes in subsurface systems and improving design criteria for constructed wetlands. More experimental data are needed to calibrate the sensitivity of local parameters in order to better assess the performance of subsurface flow constructed wetlands.

Key Words

Constructed Wetland, COMSOL, Modelling, Reactive Solute Transport, Sorption Process

ISBN:978-91-7729-436-8|TRITA-LWR.LIC2017:02|ISSN1650-8629 http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-207613