Common Reed (Phragmites australis) as a Bio Refining and Monitoring Plant of Pollution Resulting from Heavy Metals (Case Study: Dez River, Dezful, Iran)
Subject Areas : Relationship between Animal and RangelandSamar Mortazavi 1 , Alireza Ieldromi 2 , Parisa Norozi Fard 3
1 - Department of Environmental Sciences, Faculty of Natural Resource and Environment, Malayer University, P.O. Box 65719-9581863, Malayer, Hamedan, Iran
2 - Department of rengeland science, faculty of Natural Resource and Environment, Malayer University, P.O. Box 65719-9581863, Malayer, Hamedan, Iran
3 - Department of Environmental Sciences, PhD Condidate of Natural Resource and Environment, Malayer University, P.O. Box 65719-9581863, Malayer, Hamedan, Iran
Keywords:
Abstract :
Ait Ali, N., Pilar Bernal, M., Ater, M., 2002. Tolerance and bioaccumulation of copper in Phragmites australis and Zea mays. Jour. Plant and Soil 239: 103-111.
Baldantoni, D., Alfani, A., Di Tommasi, P., Bartoli, G., Virzo De Santo, A., 2004. Assessment of macro and microelement accumulation capability of two aquatic plants. Jour. Environmental Pollution 130(8): 149-156.
Bonanno, G., and Giudice, R. L., 2010. Heavy metal bioaccumulation by the organs of Phragmites australis (common reed) and their potential use as contamination indicators. Jour. Ecological Indicators 10: 639-645.
Bowen, H. J. M., 1979. Trace Element in Biochemistry. New York, Academic press, 241-244.
Bragato, C., Brix, H., Malagoli, M., 2006. Accumulation of nutrients and heavy metals in Phragmites australis (Cav.) Trin. Ex Steudel and Bolboschoenus maritimus (L.) Palla in a constructed wetland of the Venice lagoon watershed. Jour.Environmental Pollution 144: 967-975.
Bragato, C., Schiavon, M., Polese, R., Ertani, A., Pittarello, M., Malagoli, M., 2009. Seasonal variations of Cu, Zn, Ni and Cr concentration in Phragmites australis (Cav.) Trin ex steudel in a constructed wetland of North Italy. Jour. Desalination 246: 35-44.
Campbell, P. G. C., Tessier, A., Bisson, M., Bougie, R., 1985. Accumulation of copper and zinc in the yellow waterlily, Nuphar variegatum: relationships to metal partitioning in the adjacent lake sediments. Jour. Fisheries and Aquatic Science, 42(10): 23-32.
CCME (1999) (Canadian Council of Ministers of the Environment). 1999. Canadian environmental quality guidelines. Canadian Council of Ministers of the Environment Winnipeng.
Chakraborty, P., Babu, P. V. R., Sarma, V. V., 2012. A new spectroflorometric method for the determination of total arsenic in sediments and its application to kinetic speciation. Jour. Environmental Analytical Chemistry, 92: 133–147.
Cheraghi, M., Dadalahy Sohrab, A., Safahyeh, A. R., Ghanemi, K., Douraghi, A. M., 2012. investigation of accumulation of heavy metals in bed, leaves and roots of mangrove (Avicennia marina) in the province of Khuzestan, Jour. Marine Science and Technology, 11(4): 46-56. (In Persian).
Díaz-de Alba, M., Galindo-Ria˜no, M. D., Casanueva-Marenco, M. J., García-Vargas, M., Kosore, C. M., 2011. Assessment of the metal pollution, potential toxicity and speciation of sediment from Algeciras Bay (South of Spain) using chemometric tools. Jour. Hazardous Materials, 190: 177–187.
Ebadati, F., EsmailSari, A., RiahiBakhtiari A. R., 2005. A mount and how changes heavy metals in organs aquatic plants and sediment Miankaleh pond. Jour. Environmental Studies, 37: 57-53 (In Persian).
Ebrahimi, M., Jafari, M., Savaghebi, Gh., Azarnivand, H., Tawil, A. and Madrid, F., 2012. Investigation of phytoremediation species of Phragmites australis (Cav.) Trin.ex Steudel in soils contaminated with heavy metals (Case study, Industrial area Lia-Ghazvin). Jour. Rangeland, 1: 1-9. (In Persian).
Fallahi, F., Ayati, B., Ganjidoust, H., 2012. Lab Scale Study of Nitrate Removal By Phytoremediation. Jour.Water & Wastewater, 1: 57-65. (In Persian).
Fattahi kiasari, A., Fotovat, A., Astaraei, A. R., Hqqnia, Gh. H., 2010. The effect of Sulfuric acid and EDTA on phytoremediation lead in soil by three sunflower, corn and cotton. Jour. Science and Technology of Agriculture and Natural Resources, Water and Soil Science, 51: 57-68. (In Persian).
Ghanadpour, J., Zndmoqadam, A., 2010. Accumulation ofheavy metals lead, zinc, nickel and cadmiumin (Typhalatifolia) and river sediments Arvand and Bahmanshir in winter season. Jour. Wetlands, 5: 29-36. (In Persian).
Gu, Y. G., Lin, Q., Jiang, Sh. J., Wang, Zh. H., 2014. Metal pollution status in Zhelin Bay surface sediments inferred from a sequential extraction technique, South China Sea. Jour. Marine Pollution Bulletin, 81: 256–261.
Iannelli, M. A., Pietrini, F., Fiore, F., Petrilli, L., Massacci, A., 2002. Antioxidant response to cadmium in Phragmitesaustralis plants. Jour. Plant Physiolgy and Biochemistry, 40: 977–982.
Kabata-Pendias, A., H. Pendias. 2000. Trace Elements in Soils and Plants,3rd Edit, Bocaraton New York, CRC Press.
Long, E. R., Ingersoll, C. G., MacDonald, D. D., 2005. Calculation and uses of mean sediment quality guideline quotients: a critical review. Jour. Environment Science and Technology, 40: 1726–1736.
Long, E. R., MacDonald, D. D., Smith, S. L., Calder, F. D., 1995. Incidence of adverse biological effects within ranges of chemical concenterations in marine and estuarine sediments. Jour. Environmental Management, 19: 81-97.
Ma, LQ., K. M. Komar, C. Tu, W. Zhang, Y. Cai, E.D. Kenell. 2001. A fern that hyper accumulates arsenic. Jour. Nature 409: 579-582.
Malekzadeh, A., Alikhani, H. A., Savaghebi Firoozabadi, Gh. R., Zareei, M., 2011. Interaction arbuscular mycorrhizal fungies and bacteria PGPR resistant to Cadmium in phytoremediation Cadmium. Jour. Water and Soil (Agricultural Science and Technology), 25: 274-266. (In Persian).
Ngayila, N., Botineau, M., Baudu, M., Basly, J. P., 2009. Myriophyllum alterniflorum DC.Effect of low concentrations of copper and cadmium on somatic and photosyntheticendpoints: a chemometric approach. Jour. Ecolgical Indicator, 9: 307–312.
Sasmaz, A., Obek, E., Hasar. H., 2008. The accumulation of heavy metals in Typha latifolia L. grown in a stream carrying secondary effluent. Jour. Ecological Engineering, 33: 278-284.
Shirneshan, G., Riyahi Bakhtiari, A., Seyfabadi, S. J. and Mortazavi, S., 2013. Environmental Geochemistry of Cu, Zn and Pb in Sediment from Qeshm Island Persian Gulf, Iran: a Comparison Between the Northern and Southern Coast and Ecological Risk. Jour. Geochemistry International, 51(8): 670–676.
Siedlecka, A., Tukendorf, A., Sko´rzyn´ska-Polit, E., Maksymiec, W., Wo´jcik, M., 2001. Angiosperms (Asteraceae, Convolvulaceae, Fabaceae and Poaceae; other than Brassicaceae). In: Prasad, M. N. V. (Ed.), Metals in the Environment. Analysis by Biodiversity. Marcel Dekker, Inc., New York, 171–217.
Sundaray, S. K., Nayak, B. B., Lin, S., Bhatta, D., 2011. Geochemical speciation and risk assessment of heavy metals in the river estuarine sediments-A case study: Mahanadi basin, India. Jour. Hazardous Materials, 186: 1837–1846.
Suthar, S., Nema, A. K., Chabukdhara, M., Gupta, M. S. K., 2009. Assessment of metals in water and sediments of Hindon River, India: Impact of industrial and urban discharges. Jour. Hazardous Materials,171: 1088-1095.
Vardanyan, L. G., Ingole, B. S., 2006. Studies on heavy metal accumulation in aquatic macrophytes from Sevan (Armenia) and Carambolim (India) lake systems. Jour. Environmental International, 32: 208–218.
Varol, M., 2011. Assessment of heavy metal contamination in sediments of the Tigris River (Turkey) using pollution indices and multivariate statistical techniques. Jour. Hazarous Materials, 195: 355-364.
Varol, M., Şen, B., 2012. Assessment of nutrient and heavy metal contamination in surface water and sediments of the upper Tigris River, Turkey. Jour. Catena, 92: 1-10.
Welsh, R. P. F., Denny, P., 1980. The uptake of lead and copper by submerged aquatic macrophytes in two English lakes. Jour. Ecolgy 68: 443–455.
Whitton, B. A., 1975. River Ecology. Studies in Ecology. Vol. 2, Oxford, Black-well Scientific Publications 725p.
Windham, L., Weis, J. S., 2003. Uptake and distribution of metals in two dominant salt marsh macrophytes, Spartinaalterniflora (cordgrass) and Phragmites australis (common reed). Estuarine, Jour. Coastel and Shelf Science, 56: 63-72.
Yap, C. K., Ismail, A., Tan, S. G., Omar, H., 2002. Concentrations of Cu and Pb in the offshore and intertidal sediments of the west coast of Peninsular Malaysia. Jour. Environment International, 28: 467–479.
Ye, Z. H., Baker, A. J. M., Wong, M. H., Willis, A. J., 1997. Zinc, lead and cadmium tolerance, uptake and accumulation by the common reed, Phragmites australis (Cav.) Trin. ex Steudel. Jour. Ann Bot, 80: 363–370.
Yu, G. B., Liu, Y., Yu, S., Wu, S. C., Leung, A. O. W., Luo, X. S., Xu, B., Li, H. B., Wong, M. H., 2011. Nconsistency and comprehensiveness of risk assessments for heavy metals in urban surface sediments. Jour. Chemosphere, 85: 1080–1087.
Zacchini, M., Pietrini, F., Mugnozza, G., lori, V., 2008. Metal tolerance, accumulation and translocation in poplar and willow clones treated with cadmium in hydroponics. Jour. Water Air Soil Pollution, 197: 23-34.