Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Constructed wetlands (CWs) are man made vegetation filter systems, which simulate the ability of natural wetlands to remove pollutants from water. Eco-technical treatment can facilitate the re-use of process waters, drainage waters and effluents. Aquatic microbial communities, in association with plant roots and a supporting mineral matrix, are effective at removing pollutants, such as suspended solids, dissolved and particulate organic matter, nitrogen, phosphorus, metals and pathogenic organisms from effluent streams. Treatment of polluted waters in a small, self-contained CW bed is relatively inexpensive and involves low technology with a "green" image. CWs can enable contaminated waters to be re-used productively, for example in agriculture, horticulture and energy forestry. Applications for CWs include wastewater (sewage) treatment at secondary or tertiary stages, sludge drying, surface runoff (commercial, industrial), groundwater treatment, industrial and agricultural process water treatment, and for ecological habitat creation. CW systems vary in design, including surface flow vegetated channels and sub-surface soil/vegetation filters. The latter may employ horizontal flow (HF), vertical flow (VF) or tidal flow (TF) hydraulic regimes and these may be combined in hybrid systems to optimise pollutant removal. Macrophyte species planted in the bed include reeds (Phragmites), cattails (Typha), rushes (Juncus) and willow (Salix). The porosity of the bed fill material is critical for the hydraulic loading rate and retention time of effluent passing through it, which in turn determines the efficiency of water treatment. The microbial community in the bed is responsible for the processes of degradation and chemical transformation, which result in pollutant removal. Both aerobic and anaerobic processes are involved, but degradation of carbonaceous matter (BOD) to CO2 and transformation of ammonia to nitrate require biological oxidation, and hence a continual supply of oxygen. This is achieved most efficiently in compact VF systems; as the surface is flooded, air is forced into the bed, while effluent percolates downwards through the matrix. Horizontal flow (HF) beds typically achieve lower oxygen transfer rates but, with largely anaerobic conditions, they are effective in removing nitrogen to atmosphere via de-nitrification. The role of plant roots in providing an oxygen source in the subsurface environment, according to the Root-Zone Model, and in creating reduced/ oxidised micro-environments in the matrix, is considered. Evidence for the release of oxygen by plant roots and the presence of aerobic/anaerobic micro-gradients is discussed, with reference to measurements in laboratory microcosms and in-situ field systems. The importance of plant uptake in removing N and P from effluent is assessed. CWs are effective in treating polluted waters arising from a wide range of domestic, industrial and agricultural operations and are particularly appropriate for isolated rural situations, enabling water of acceptable quality to be discharged to environment, or to be re-used locally as fertilizer. CW technology offers a cost-effective means of protecting water resources from contamination, whilst providing local habitat diversification.
Czasopismo
Rocznik
Tom
Strony
78--89
Opis fizyczny
Bibliogr. 50 poz., rys., tab., wykr.
Twórcy
autor
- School of Biosciences, Cardiff University, PO Box 915, Cardiff CF10 3TL, UK, randerson@cf.ac.uk
Bibliografia
- Allen, W.C., P.B. Hook, J.A. Biederman, O.R. Stein. 2002. Temperature and wetland plant species effects on wastewater treatment and root zone oxidation. Journal of Environmental Quality 31: 1010-1016.
- Armstrong, W., D. Cousins, J. Armstrong, D.W. Turner, P.M. Beckett. 2000. Oxygen distribution in wetland plant roots and permeability barriers to gas-exchange with the rhizosphere: a microelectrode and modelling study with Phragmites australis. Annals of Botany 86: 687-703.
- Aronsson, P. 2000. Nitrogen retention in vegetation filters of short-rotation willow coppice. Doctoral Thesis, Swedish University of Agricultural Sciences, Uppsala, Sweden.
- Aronsson, P., K.L. Perttu. 2001. Willow vegetation filters for wastewater treatment and soil remediation combined with biomass production. Forestry Chronicle 77: 293-299.
- Brix, H. 1987. Treatment of wastewater in the rhizosphere of wetland plants - the root zone method. Water Science and Technology 19: 107-119.
- Brix, H. 1993. Wastewater treatment in constructed wetlands: system design, removal processes and treatment performance. In: Constructed Wetlands for Water Quality Improvement (ed. G.A. Moshiri), pp. 9-22. CRC, Boca Raton.
- Brix, H. 1997. Do macrophytes play a role in constructed treatment wetlands? Water Science and Technology 35: 11-17.
- Brix, H. 2003. Danish experiences with wastewater treatment in constructed wetlands. In: The Use of Aquatic Macrophytes for Wastewater Treatment in Constructed Wetlands (ed. V. Diaz, J. Vymazal), pp. 327-361. Ministerio das Cidades, Ordenamento do Territorio E Ambiente, Lisboa, Portugal.
- Brix, H., C.A. Arias. 2005. The use of vertical flow constructed wetlands for on-site treatment of domestic wastewater: New Danish guidelines. Ecological Engineering 25: 491-500.
- Brix, H., H.H. Schierup. 1989. Use of aquatic macrophytes in water pollution control. AMBIO AMBOCX 18: 100-107.
- Cooper, P.F. 1999. A review of the design and performance of vertical flow and hybrid reed bed treatment stystems. Water Science and Technology 40: 1-9.
- Cooper, P.F. 2001. Nitrification and denitrification in hybrid constructed wetland systems. In: Transformations of Nutrients in Natural and Constructed Wetland (ed. J. Vymazal), pp. 257-270. Backhuys Publs. Leiden. The Netherlands.
- Cooper, P.F. 2005. The performance of vertical flow constructed wetland systems with special reference to the significance of Oxygen Transfer and Hydraulic Loading Rates. Water Science and Technology 51: 81-90.
- Cooper, P.F., G.D. Job, M.B. Green, R.B.E. Shutes. 1996. Reed Beds and Constructed Wetlands for Wastewater Treatment. 184 p. WRc Publ., Medmenham, Marlow, Bucks. U.K.
- Cooper, P.F., M. Smith, H. Maynard. 1997. The design and performance of a nitrifying vertical flow reed bed system. Water Science and Technology 35: 215-221.
- Dalyell, T. 1995. Down the valley something stirs. New Scientist 21. October 1995. http://www.newscientist.com/article/mg14820006. 400-down-the-valley-something-stirs.html
- Dickinson, N.M., I.D. Pulford. 2005. Cadmium phytoextraction using short-rotation coppice Salix: the evidence trail. Environment International 31: 609-613.
- Dickinson, N.M., T. Punshon, R.B. Hodkinson, N.W. Lepp. 1994. Metal tolerance and accumulation in willows. In: Willow Vegetation Filters for Municipal Wastewater and Sludges: A Biological Purification System (ed. P. Aronsson, K. Perttu), pp. 121-127. Report 50, Swedish University of Agricultural Sciences, Uppsala, Sweden.
- Dimitriou, I., P. Aronsson. 2003. Wastewater phytoremediation treatment systems in Sweden using short rotation willow coppice. In: SRC Crops for Bioenergy: New Zealand, pp. 225-228. Swedish University of Agricultural Sciences, Uppsala.
- Duggan, J. 2005. The potential for landfill leachate treatment using willows in the UK-A critical review. Resources, Conservation & Recycling 45: 97-113.
- Elowson, S. 1999. Willow as a vegetation filter for cleaning of polluted drainage water from agricultural land. Biomass & Bioenergy 16: 281-290.
- EPA. 1988. Constructed wetlands and aquatic plant systems for municipal waste water treatment: Design Manual. 83 p. US EPA Publication 625/1-88/022, Centre for Environmental Research Information, Cincinnati, OH 45268.
- Evans, D.E. 2003. Aerenchyma formation. New Phytologist 161: 35-49.
- Green, M.B., J. Uptown. 1995. Constructed reed beds: an appropriate technology for small communities. Water Science and Technology 32: 339-348.
- Hasselgren, K. 1998. Use of municipal waste products in energy forestry: highlights from 15 years of experience. Biomass & Bioenergy 15: 71-74.
- Hiley, P.D. 1995. The reality of sewage treatment using wetlands. Water Science and Technology 32: 329-338.
- Hook, P.B., O.R. Stein, W.C. Allen, J.A. Biederman. 2003. Plant species effects on seasonal performance patterns in model subsurface wetlands. Advances in Ecological Science 11: 87-106.
- Kadlec, R.H., R.L. Knight. 1996. Treatment Wetlands. 893p. CRC Press LLC, Florida.
- Kangas, P.C. 2004. Ecological Engineering: Principles and Practice. 504 p. CRC Press LLC, Florida.
- Kickuth, R. 1981. Abwasserreinigung in Mosaikmatrizen aus anaeroben und aeroben Teilbezierken. Grundlangen der Abwasserreiningung. GWF Schriftreihe Wasser-Abwasser, 19. Oldenburg Verlag, Oldenburg.
- Kowalik, P.J., M. Mierzejewski, H. Obarska-Pempkowiak, I. Toczylowska. 1995. Constructed wetlands for wastewater treatment of small communities. 70 p. Center of Environmental Studies, CENVIG, Polytechnical University of Gdansk.
- Kowalik, P.J., M. Mierzejewski, P.F. Randerson, H.G. Williams. 2004. Performance of subsurface vertical flow constructed wetlands receiving municipal wastewater. Archives of Hydro-Engineering & Environmental Mechanics 51: 349-370.
- Kowalik, P.J., P.F. Randerson. 1994. Nitrogen and phosphorus removal by willow stands irrigated with municipal wastewater - a review of the Polish experience. Biomass & Bioenergy 6: 133-139.
- Kowalik, P.J, F.M. Slater, P.F. Randerson. 1996. Constructed wetlands for landfill leachate treatment. In: Ecotechnics for a Sustainable Society: Proceedings of Ecotechnics 95 - International Symposium on Ecological Engineering (ed. L. Thofelt, A. Englund), pp. 189-200. Mid Sweden University, Harnosand, Sundsvall, Ornskoldsvik, Ostersund.
- Landberg, T., M. Greger. 1994. Can heavy metal tolerant clones of Salix be used as vegetation filters on heavy metal contaminated land? In: Willow Vegetation Filters for Municipal Wastewater and Sludges: A Biological Purification System (ed. P. Aronsson, K. Perttu), pp. 133-144. Uppsala, Swedish University of Agricultural Sciences, Uppsala, Sweden.
- Lloyd, D., K. Thomas, D. Price, B. O’Neil, K. Oliver, T. Williams. 1996. A membrane-inlet mass spectrometer miniprobe for direct simultaneous measurement of multiple gas species with spatial resolution of 1mm. Journal of Microbiological Methods 25: 145-151.
- Lloyd, D., K.L. Thomas, G. Cowie, J.D. Tammam, A.G. Williams. 2002. Direct interface of chemistry to microbiological systems: membrane inlet mass spectrometry. Journal of Microbiological Methods 48: 289-302.
- Ostman, G. 1994. Cadmium in Salix – a study of the capacity of Salix to remove cadmium from arable soils. In: Willow Vegetation Filters for Municipal Wastewater and Sludges: A Biological Purification System (ed. P. Aronsson, K. Perttu), pp. 153-155. Report 50, Swedish University of Agricultural Sciences, Uppsala, Sweden.
- Perttu, K.L., P.J. Kowalik. 1997. Salix vegetation filters for purification of waters and soils. Biomass & Bioenergy 12: 9-19.
- Randerson, P.F. 2007. Water quality and Constructed Wetlands. In: Water and Agriculture. Report from International Conference (Bertebos), 14-16 May 2006, Falkenberg, Sweden, pp. 35-38.
- Kungl. Skogs-och Lantbruksakademiens Tidskrift 1 2007. Randerson, P.F., F.M. Slater. 2005. The role of willow plants in the treatment of iron-rich landfill leachate. In: Proceedings of the 6 th International Conference on Environmental Engineering, Vilnius, Lithuania, pp. 420-424. Vilnius Gediminas Technical University.
- Randerson, P.F., G. Jordan, H.G. Williams. 2005. The role of willow roots in sub-surface oxygenation of vegetation filter beds - mass spectrometer investigations in Wales, U.K. In: Wastewater Treatment in Wetlands. pp. 159-165. Technical University of Gdansk, Poland.
- Riddel-Black, D. 1994. Heavy metal uptake by fast growing willow species. In: Willow Vegetation Filters for Municipal Wastewater and Sludges: A Biological Purification System (ed. P. Aronsson, K. Perttu ), pp. 145-152. Report 50, Swedish University of Agricultural Sciences, Uppsala, Sweden.
- Ryszkowski, L., A. Bartoszewicz, J. Marcinek. 1990. Bariery biogeochemiczne [Biogeochemical barriers]. In: Obieg wody i bariery biogeochemiczne w krajobrazie rolniczym [Water Circulation and Biogeochemical Barriers in Agricultural Landscape] (in Polish), pp. 167-181. Poznan, Zaklad Badan Srodowisk Rolniczych i Lesnych, Polish Academy of Sciences (PAN).
- Ryszkowski, L., A. Kedziora. 2007. Modification of water flows and nitrogen fluxes by shelterbelts. Ecological Engineering 29: 388-400.
- Sorrel, B.K, W. Armstrong. 1994. On the difficulties of measuring oxygen release by root systems of wetland plants. Journal of Ecology 82: 177-183.
- Stottmeister, U., A. Wießner, P. Kuschk, U. Kappelmeyer, M. Kästner, O. Bederski, R.A. Müller, H. Moorman. 2003. Effects of plants and microorganisms in constructed wetlands for wastewater treatment. Biotechnology Advances 22: 93-117.
- Williams, H.G., P.F. Randerson, F.M. Slater, R.J. Heaton. 2001. Can willow roots oxygenate leachate in vegetation filter beds? - A mass spectrometer investigation in Wales. In: Leachate and wastewater treatment with high-tech and natural systems (ed. W. Hogland, V. Vysniauskaite), pp. 75-81. University of Kalmar, Sweden.
- Wilson, F.E.A., W.M. Dawson. 2001. Bioremediation of municipal wastewater using short rotation coppice. Aspects of Applied Biology 65: 329-335.
- Wong, C.H., G.W. Barton, J.P. Barford. 2003. The nitrogen cycle and its application in wastewater treatment. In: The Handbook of Water and Wastewater Microbiology (ed. D. Mara, N. Horan), pp. 427-440. Academic, London.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BAR0-0062-0072