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Zinc and Chromium removal mechanisms from industrial wastewater by using water hyacinth, eicchonia crassipes

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par John Gakwavu Rugigana
National University of Rwanda - Master's in WREM (water resources and environmental management) 2007
  

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References

Alick B. M., 2002. The potential use of Cyperus papyrus constructed wetlands for the treatment of mine water containing Zinc and Lead, MSc. Thesis, IHE Delft The Netherlands 214, 79-85.

Allen, L.H., Sinclair, T.R., Bennett, J.M., 1997. Evapotranspiration of vegetation of Florida: perpetuated misconceptions versus mechanistic processes. In: Proceedings of the Soil and Crop Science Society of Florida, vol. 56. pp. 1-10.

Alloway, B. J., 1990. Soil processes and the behaviour of metals, in Alloway, B. J. (Ed). Heavy metals in soils, Blackie and Son Ltd, London pp.7-28.

APHA/AWWA/WEF, 2005, Standard methods for the examination of water and wastewater, APHA, 21st edition, Washington, DC. 2001-3710.

Arisz, W. H., 1961. Symplasm theory of salt uptake into and transports in parenchymatic

tissues. In : Recent Advances in Botany, vol 11, pp 1125-28. University of Toronto. Babu M., 2001. Potential removal of Zinc by Cyperus papyrus from an Artificial Wetland,

MSc. Thesis, IHE Delft The Netherlands

Babu, R.M., Sajeena, A., Seetharaman, K., 2003. Bioassay of the potentiality of Alternaria alternate (Fr.) keissler as a bioherbicide to control water hyacinth and other aquatic weeds. Crop Protection 22, 1005-1013.

Baker, A. J. M., Walker, P. L. 1990. Ecophysiology of metal uptake by tolerant plants, heavy metal tolerance in Plants. In: Shaw AJ. Evolutionary Aspects. CRC Press, Boca Raton. 155-177.

Barron, L., Weand, Judkins, J., F.,and Benefield, L., D., 1982. Process chemistry for

water and wastewater treatment, Prentice-hall international, Inc, London.

Center, T.D., Hill, M.P., Cordo, H., Julien, M.H., 2002. Waterhyacinth. In: Van Driesche,

R., Biological Control of Invasive Plants in the Eastern United States. USDA Forest

Service Publication FHTET-2002-04, 41-64.

Chang, L.W., 1996. Toxicology of Metals, CRC Press, Boca Raton, FL.

Chua, H., 1998: Bio-accumulation of environmental residues of rare earth elements in aquatic flora Eichhornia crassipes (Mart.) Solms. in Guangdong Province of China. The Science of Total environment.

Denny, P., 1980. Solute movement in submerged angiosperms. Biol Rev 55, 65-92. Denny, P., 1987. Mineral cycling by wetland plants - a review.Arch Hydrobiol 27, 27,1- 25.

Denny, P., Roland, B., Eldad, T., and Paul, M., 1995. Heavy metal contamination of Lake George (Uganda) and its wetlands. Hydrobiologia 297, 229-239

Espinoza-Quinones, F. R., Zacarkim, C. E., Palacio, S. M., Obreg'on, C. L., Zenatti, D. C., Galante, R. M., Rossi, N., Rossi, F. L., Pereira, I. R. A., Welter, R. A., 2005. Removal of Heavy Metal from Polluted River Water Using Aquatic Macrophytes Salvinia sp. N'ucleo de Biotecnologia e Desenvolvimento de Processos Qu'ýmicos - NBQ, Universidade Estadual do Oeste do Paran - UNIOESTE/Campus de Toledo, PR, Brazil.

Grodowitz, M.J., Center, T.D., Freedman, J.E., 1997. A Physiological Age-Grading System for Neochetina eichhorniae (Warner) (Coleoptera: Curcuionidae), a Biological Control Agent of Water Hyacinth, Eichhornia crassipes (Mart.) Solms. Biological Control 9, 89-105.

Hasan, S.H., Talat, M., Rai S., 2006. Sorption of cadmium and zinc from aqueous solutions by water hyacinth (Eichchornia crassipes) Elsevier, Bioresource Technology 98 (2007) 918-928

Jayaweera, M. W., Kasturiarachchi, J. C., Kularatne, R. K. A. and Wijeyekoon, S. L. J., 2007. Removal of Aluminium by constructed wetlands with water hyacinth grown under different nutritional conditions, Department of chemical and process engineering, University of Moratuwa, Sri Lanka.

Julien, M.H., Orapa, W., 1999. Successful biological control of water hyacinth (Eichhornia crassipes) in Papua New Guinea by the weevils Neochetina bruchi and Neochetina eichhorniae (Coleoptera: Curcuionidae). In: N.R., Spencer (ed.), Proceedings of the X International Symposium on Biological Control of Weeds, Montana State University, Bozeman, Montana, USA, p. 1027.

Kabata-Pendias, A, Pendias, H., 1989. Trace Elements in the Soil and Plants. Florida: CRC Press.

Kara, Y., 2005. Bioaccumulation of Cu, Zn and Ni from wastewater by treated Nasturtium officinale. Department of Biology, Faculty of science and Art.

Keith, C., Borazjani, H., S. Diehl, V., Su2, Y., and Baldwin, B.S., 2006. Removal of Copper, Chromium, and Arsenic by Water Hyacinths, Forest Products Department, Forest and Wildlife Research Center, Mississippi State University, MS.

Lasat, M., M., 2000. Phytoextraction of metals from contaminated soil: a review of plant/soil/metal interaction and assessment of pertinent agronomic issues. J Hazar Subs Res 2, 1-23.

Lehmann, M., Zouboulis, A.I. Matis, K.A., 1999. Removal of metal ions from dilute aqueous solutions: a comparative study of inorganic sorbent materials, Chemosphere 39. 881-892.

Lesage, E., 2006. Behaviour of heavy metals in constructed treatment wetlands. PhD thesis. Faculty of Bioscience Engineering, Ghent University, Ghent, Belgium, 247 pp.

Lin YX and Zhang Xm., 1990. Accumulation of heavy metals and the variation of amino acids and protein in Eichhornia crassipes (Mart.) solms in the Dianchi lake. Oceanol Limnol Sinica 21 21, 179-84 (In Chinese).

Lindsey K., Hirt H.M., 1999. Use Water Hyacinth! A Practical Hanbook of uses for the Water Hyacinth from Across the World. Anamed: Winnenden, 114.

Liu J., Dong Y., Xu H., Wang D., Xu J., 2007. Accumulation of Cd, Pb and Zn by 19 wetland plant species in constructed wetland, Elsevier, Journal of Hazardous Materials 147 (2007) 947-953

Lubberding, H., Patrick, D., Gijzen, H., 1999. Removal of heavy metal by macrophytes in wetland and stabilization ponds. COST 837, Lausanne, Working group 2.

Lubberding, H., Barbiker, F., Kitimbo, P., Gijzen, H., 2000. Potential removal of heavy metals from wetlands and stabilization ponds by two aquatic macrophytes. COST 837, Parma, Working group 2

Lubberding, H., Martine, L., Patrick, D., Gijzen, H., 2001. Zinc removal by the macrophytes Pistia stratiotes. COST 837, Madrid, Working group 2-toxic metal: 33.

Maine MA, Duarte MV and Sune NL . 2001. Cadmium uptake by floating macrophytes.

Wat Res 35(11) 11), 2629-34.

Maine, M.A., Sune, N.L., Panigatti, M.C., Pizarro, M.J.,1999. Relationships between water chemistry and macrophyte chemistry in lotic and lentic environment. Arch. Hydrobiol. 145 (2), 129-145.

Marschner, H., 1986. Mineral nutrition in higher plants. Academic Press, London.

Matagi, S.V., Swai, D. and Mugabe, R., 1998. A review of heavy metal removal mechanisms in wetlands. Afr J Trop Hydrobiol 8, 8,23-5.

Meggo, R., 2001. Allocation pattern of Lead and Zinc in Cyperus papyrus and Lemna gibba. Msc Thesis DEW 147 DELFT IHE, Netherlands pp44.

Memon A. R., 2000. Heavy Metal Accumulation and Detoxification Mechanisms in Plants, Marmara Research Center, Institute for Genetic Engineering and Biotechnology.

Mullen, M.D., Wolf, D.C., Ferris, F.G., Beveridge, T.J., Flemming, C.A., Bailey, G.W.,

1989. Bacterial sorption of heavy metals, Appl. Environ. Microbiol. 55-3143-3149. Mungur, A.S., Shutes, R.B.E., Revit, D.M. and House, M.A., 1997. An assessment of

metal removal by a laboratory scale wetland. Wat. Sci. Tech. Vol. 35, 125-133
National Geographic - Television & Film, 2004. Strange Days on Planet Earth, First

Episode: Invaders.

Nevena N., Ljubinko J. Potential Use of Water Hyacinth (E. CRASSIPENS) for

Wastewater Treatment in Serbia 1Institute of Forestry, 2 Center for

multidisciplinary studies, University of Belgrade Belgrade, Serbia and Montenegro. Nkuranga, E., 2007. Heavy metal removal and accumulation by an Urban Natural

Wetland: the Nyabugogo Swamp, Rwanda. MSc Thesis ES 07.19, Delft,

UNESCO-IHE, Netharlands, pp73

Nriogo, J. O., 1979. Global inventory of natural and anthropogenic emissions of trace metals to the atmosphere. Nature 279: 409-411.

Obarska, H. and Pempkowiak, 2001. Retention of selected heavy metals: Cd, Cu, Pb in a hybrid wetland system. Wat. Sci. Tech. Vol. 44 (11-12), 463-468

Kelderman, P., 2000. Uptake and adsorption of Lead, Copper and Zinc by Lemna gibba, MSc. Thesis, IHE Delft The Netherlands.

Prasad M.N.V. and Freitas H.M.O., 2003. Metal hyperaccumulation in plants - Biodiversity prospecting for phytoremediation technology. Electronic Journal of Biotech. Vol. 6 (3).

Rai, U. N., Sinha S., Tripathi R. D., Chandra P., 1995. Wastewater treatability potential

of some aquatic macrophytes: removal of heavy metals. Ecol. Engin., 5: 5-12.
Samecka-Cymermann A. and Kempers, A. J., 1996. Ecotoxicology and Environmental

Safety 35, 242.

Sarabjeet S. A. and Dinesh G., 2005. Microbial and plant derived biomass for removal of heavy metals from wastewater, Elsevier, Bioresource Technology 98 (2007) 2243-2257

So, L.M., Chu, L.M., Wong, P.K., 2003. Microbial enhancement of Cu2+ removal
capacity of Eichhornia crassipes (Mart.). Chemosphere 52, 1499-1503.

Srivastov, R. K., Gupta S. K., K. D. P. Nýgam., Vasudevan P.,1994. Treatment of chromium and nickel in wastewater by using aquatic plants. Water Resources, 28 (7): 1631-1638.

Stephenson, M., G. Turner, P. Pope, J. Colt, A. Knight, and Tchobanoglous, G., 1980. The Use and Potential of Aquatic Species for Wastewater Treatment. Publication No. 65, California State Water Resources Control Board.

Stratford HK, William TH and Leon A., 1984. Effects of heavy metals on water hyacinths (Eichhornia crassipes). Aquat Toxicol 5(2), 117-28.

Vesk, P.A., Nockolds, C. E., and Allaway W. G., 2006. Metal localization in water hyacinth roots from an urban wetland, plant, Cell and Environment (1999)22, 149- 158. School of biological sciences, Australia.

Volesky, B., 2001. Detoxification of metal-bearing effluents: biosorption for the next century, Hydrometallurgy 59 203-216.

Volesky, B., Holan, Z.R., 1995. Biosorption of heavy metals, Biotechnol. Prog. 11-235- 250.

Wilson, J.R., Holst, N., Rees, M., 2005. Determinants and patterns of population growth in water hyacinth. Aquatic Botany 81, 51-67.

Xiaomei L., Maleeya K. Prayad P. and Kunaporn H. 2004. Removal of Cadmium and Zinc by Water Hyacinth, Eichhornia crassipes, Department of Biology, Faculty of Life Science, Hubei University, Wuhan 430062, P. R. China.

Young, S., K., Lee, J., U., Kim, K., W., 2006. Biosorption of Cr(III) and Cr(IV) onto the cell surface of Pseudomonas aeruginosa, Department of Environmental Science and Engineering, Gwangju Institute of Science and Technology (GIST), Gwangju 500-712, South Korea. Biochemical Engineering Journal 36 54-58.

Zayed, A., Gowthaman S., Terry N., 1998. Phytoaccumulation of trace elements by wetland plants: I. Duck weed. J. Environ. Qual., 27: 715-721.

Zhihong, Y., Alan, J. M. B., Ming-Hung, W. and Arthur, J. W., 1998. Zinc, lead and cadmium accumulation and tolerance in Typha latifolia as affected by iron plaque on the root surface. Aquatic botany 61, 55-67

Zhu Y.L, Qian, J. H., Zayed A., Yu M., Terry N., 1999. Phytoaccumulation of trace elements by wetland plants III. Uptake and accumulation often trace elements by twelve plant species. J. Environ. Qual., 28 (5): 1448-1455.

Zhu, Y. L., A. M. Zayed J. H. Qian M. De Soltan M. E., Rashed M. N., 2003. Laboratory study on the survival of water hyacinth under several conditions of heavy metal concentrations. Advan. Environ. Res., 7: 321- 334.

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