The metal uptake of plants on the landfill sites in Bereg County
September 11, 2012
The metal uptake of plants on the landfill sites in Bereg County
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| Title: | The metal uptake of plants on the landfill sites in Bereg County |
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| Article_Title: | The metal uptake of plants on the landfill sites in Bereg County |
| Authors: | Judit I. Halasz, Sándor Balázsy, Angela Kolesnyk, Erzsebet Krausz |
| Affiliation: | Institute of Biology, College of Nyíregyháza, Nyíregyháza, Hungary Department of Environmental Science, College of Nyíregyháza, Nyíregyháza, Hungary Uzhgorod National University, Uzhgorod, Ukraine |
| Abstract: | Our time is characterized by active struggle against various environmental pollutants. The soil factor is determinative and most informative for demonstration and detection of the dumps’ possible impact on the environment. We investigated the total copper, zinc, lead of the soil in landfills, as well as the corresponding metal contents in the plants growing there in Bereg County. Metal content of the contaminated soils Cu 47.9-34.8 mg/kg, Pb 67.18-43.7 mg/kg, Zn 237.5-228.2 mg/kg, and on the control: Cu 19.5 mg/kg, Pb 15.39 mg/kg, Zn 23.2 mg/kg. The contents of heavy metal in the plants growing within the landfill sites Cu 15.16-15.26 mg/kg, Pb 1.87-2.79 mg/kg, Zn 33,38-33,89 mg/kg and on the control: Cu 12,55 mg/kg, Pb 0.89 mg/kg, Zn 26,55 mg/kg. Numerous adventive plants (Urtica spp., Artemisia spp., Stenactis annua (L.) Nul, Polygonum sachalinense Fr. Schmidt, etc.) that force out autochthonous species are bioindicators of the polluted areas. |
| Keywords: | plants, contaminated soil, heavy metal |
| References: | Alloway BJ, Jackson AP, Morgan H, The accumulation of cadmium by vegetables grown on soils contaminated from a variety of sources. Sci Total Environ, 91, 223–36 1990. Arnon DI, Stout PR, The essentially of certain elements inminute quantity for plants with special reference to copper. Plant Physiologie, 14, 371–5, 1939. Baker AJM, Accumulators and excluders strategies in the response of plants to heavy metals. Journal of Plant Nutrition, 3, 643, 1981. Baker AJM, Brooks RR, Terrestrial higher plants which hyperaccumulate metallic elements a review of their distribution, ecology and phytochemistry. Biorecovery, 1, 81-126, 1989. Baker AJM, McGrath SP, Reeves RD, Smith JAC, Metal hyperaccumulator plants: a review of the ecology and physiology of a biological resource for phytoremediation of metal-polluted soils. In: Terry N, Banuelos Q, editors. Phytoremediation of contaminated soil and water. Boca Raton (FL)7 Lewis Publishers; 85– 197, 2000. Ghanati F, Morita A, Yokota H, Effects of aluminum on the growth of tea plant and activation of antioxidant system. Plant Soil,;276, 133–41, 2005. Gomez A, The nanoparticle formation and uptake of precious metals by living alfalfa plants. Master Thesis, University of Texas at El Paso; 2002 Huang JW, Cunningham SD, Lead phytoextraction: species variation in lead uptake and translocation. New Phytologie, 134, 73–84, 1996. Joonki Y, Xinde C, Qixing Z, Lena QM, Accumulation of Pb, Cu and Zv in native plants growing on a contaminated Florida site. Science of the Total Environment, 368, 456-464, 2006. Jung MC, Thornton I, Heavy metal contamination of soils and plants in the vicinity of a lead–zinc mine, Korea. Appl Geochemistry, 11, 53–9, 1996. Kabata-Pendias A, Pendias H, Trace elements in soils and plants. Boca Raton, FL: CRC Press Inc.; 1992. Kim IS, Kang HK, Johnson-Green P, Lee EJ, Investigation of heavy metal accumulation in Polygonum thunbergii for phytoextraction. Environ Pollution, 126, 235–43, 2003. Landberg T, Greger M, Differences in uptake and tolerance to heavy metals in Salix from polluted and unpolluted areas. Appl Geochemistry, 11, 175– 80, 1996. McGrath SP, Zhao FJ, Dunham SJ, Crosland AR, Coleman K, Long-term changes in extractability and bioavailability of zinc and cadmium after sludge application. J Environ Qual., 29, 875– 83, 2000. Ma LQ, Komar KM, Tu C, Zhang W, A fern that hyperaccumulates arsenic. Nature, 409, 579, 2001 McGrath SP, Zhao FJ, Lombi E, Phytoremediation of metals, metalloids, and radionuclides. Adv Agric, 75, 1–56, 2002. Mcgrath SP, Zhao FJ, Phytoextraction of metals and metalloids from contaminated soils. Curr Opin Biotechnologie, 14, 1–6, 2003. Pitchtel J, Kuroiwa K, Sawyerr HT, Distribution of Pb, Cd, and Ba in soils and plants of two contaminated sites. Environ Pollution, 110, 171–8, 2000. Pulford ID, Watson C, Phytoremediation of heavy metal-contaminated land by tree—a view. Environ International, 29:5, 29–40. 2003. Rosselli W, Keller C, Boschi K, Phytoextraction capacity of trees growing on metal contaminated soil. Plant Soil, 256, 265–72, 2003. Shu WS, Ye ZH, Lan CY, Zhang ZQ, Wong MH, Lead, zinc and copper accumulation and tolerance in populations of Paspalum distichum and Cynodon dactylon. Environ Pollution, 120, 445–53, 2002. Stoltz E, Greger M, Accumulation properties of As, Cd, Cu, Pb and Zn by four wetland species growing on submerged mine tailings. Environ Exp Botanica, 47, 271– 80, 2002 Taiz L, Zeiger E, Plant physiology. 2nd ed. Sunderland, MA: Sinauer; 1998. Yanqun Z, Yuan L, Jianjun C, haiyan C, Li Q, Schvartz C, Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining in Yunnan, China. Environmental International 31, 755-762, 2005. |
| Read_full_article: | pdf/22-2012/22-2-2012/SU22-2-2012-Halasz.pdf |
| Correspondence: | Judit L. Halász. College of Nyíregyháza, Institute of Biology, Nyíregyháza, Nyíregyháza-4400, Sóstói út 31/b. Hungary, email: halaszj@nyf.hu |
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| Article Title: | The metal uptake of plants on the landfill sites in Bereg County |
| Authors: | Judit I. Halasz, Sándor Balázsy, Angela Kolesnyk, Erzsebet Krausz |
| Affiliation: | Institute of Biology, College of Nyíregyháza, Nyíregyháza, Hungary Department of Environmental Science, College of Nyíregyháza, Nyíregyháza, Hungary Uzhgorod National University, Uzhgorod, Ukraine |
| Abstract: | Our time is characterized by active struggle against various environmental pollutants. The soil factor is determinative and most informative for demonstration and detection of the dumps’ possible impact on the environment. We investigated the total copper, zinc, lead of the soil in landfills, as well as the corresponding metal contents in the plants growing there in Bereg County. Metal content of the contaminated soils Cu 47.9-34.8 mg/kg, Pb 67.18-43.7 mg/kg, Zn 237.5-228.2 mg/kg, and on the control: Cu 19.5 mg/kg, Pb 15.39 mg/kg, Zn 23.2 mg/kg. The contents of heavy metal in the plants growing within the landfill sites Cu 15.16-15.26 mg/kg, Pb 1.87-2.79 mg/kg, Zn 33,38-33,89 mg/kg and on the control: Cu 12,55 mg/kg, Pb 0.89 mg/kg, Zn 26,55 mg/kg. Numerous adventive plants (Urtica spp., Artemisia spp., Stenactis annua (L.) Nul, Polygonum sachalinense Fr. Schmidt, etc.) that force out autochthonous species are bioindicators of the polluted areas. |
| Keywords: | plants, contaminated soil, heavy metal |
| References: | Alloway BJ, Jackson AP, Morgan H, The accumulation of cadmium by vegetables grown on soils contaminated from a variety of sources. Sci Total Environ, 91, 223–36 1990. Arnon DI, Stout PR, The essentially of certain elements inminute quantity for plants with special reference to copper. Plant Physiologie, 14, 371–5, 1939. Baker AJM, Accumulators and excluders strategies in the response of plants to heavy metals. Journal of Plant Nutrition, 3, 643, 1981. Baker AJM, Brooks RR, Terrestrial higher plants which hyperaccumulate metallic elements a review of their distribution, ecology and phytochemistry. Biorecovery, 1, 81-126, 1989. Baker AJM, McGrath SP, Reeves RD, Smith JAC, Metal hyperaccumulator plants: a review of the ecology and physiology of a biological resource for phytoremediation of metal-polluted soils. In: Terry N, Banuelos Q, editors. Phytoremediation of contaminated soil and water. Boca Raton (FL)7 Lewis Publishers; 85– 197, 2000. Ghanati F, Morita A, Yokota H, Effects of aluminum on the growth of tea plant and activation of antioxidant system. Plant Soil,;276, 133–41, 2005. Gomez A, The nanoparticle formation and uptake of precious metals by living alfalfa plants. Master Thesis, University of Texas at El Paso; 2002 Huang JW, Cunningham SD, Lead phytoextraction: species variation in lead uptake and translocation. New Phytologie, 134, 73–84, 1996. Joonki Y, Xinde C, Qixing Z, Lena QM, Accumulation of Pb, Cu and Zv in native plants growing on a contaminated Florida site. Science of the Total Environment, 368, 456-464, 2006. Jung MC, Thornton I, Heavy metal contamination of soils and plants in the vicinity of a lead–zinc mine, Korea. Appl Geochemistry, 11, 53–9, 1996. Kabata-Pendias A, Pendias H, Trace elements in soils and plants. Boca Raton, FL: CRC Press Inc.;1992. Kim IS, Kang HK, Johnson-Green P, Lee EJ, Investigation of heavy metal accumulation in Polygonum thunbergii for phytoextraction. Environ Pollution, 126, 235–43, 2003. Landberg T, Greger M, Differences in uptake and tolerance to heavy metals in Salix from polluted and unpolluted areas. Appl Geochemistry, 11, 175– 80, 1996. McGrath SP, Zhao FJ, Dunham SJ, Crosland AR, Coleman K, Long-term changes in extractability and bioavailability of zinc and cadmium after sludge application. J Environ Qual., 29, 875– 83, 2000. Ma LQ, Komar KM, Tu C, Zhang W, A fern that hyperaccumulates arsenic. Nature, 409, 579, 2001 McGrath SP, Zhao FJ, Lombi E, Phytoremediation of metals, metalloids, and radionuclides. Adv Agric, 75, 1–56, 2002. Mcgrath SP, Zhao FJ, Phytoextraction of metals and metalloids from contaminated soils. Curr Opin Biotechnologie, 14, 1–6, 2003. Pitchtel J, Kuroiwa K, Sawyerr HT, Distribution of Pb, Cd, and Ba in soils and plants of two contaminated sites. Environ Pollution, 110, 171–8, 2000. Pulford ID, Watson C, Phytoremediation of heavy metal-contaminated land by tree—a view. Environ International, 29:5, 29–40. 2003. Rosselli W, Keller C, Boschi K, Phytoextraction capacity of trees growing on metal contaminated soil. Plant Soil, 256, 265–72, 2003. Shu WS, Ye ZH, Lan CY, Zhang ZQ, Wong MH, Lead, zinc and copper accumulation and tolerance in populations of Paspalum distichum and Cynodon dactylon. Environ Pollution, 120, 445–53, 2002. Stoltz E, Greger M, Accumulation properties of As, Cd, Cu, Pb and Zn by four wetland species growing on submerged mine tailings. Environ Exp Botanica, 47, 271– 80, 2002 Taiz L, Zeiger E, Plant physiology. 2nd ed. Sunderland, MA: Sinauer; 1998. Yanqun Z, Yuan L, Jianjun C, haiyan C, Li Q, Schvartz C, Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining in Yunnan, China. Environmental International 31, 755-762, 2005. |
| *Correspondence: | Judit L. Halász. College of Nyíregyháza, Institute of Biology, Nyíregyháza, Nyíregyháza-4400, Sóstói út 31/b. Hungary, email: halaszj@nyf.hu |
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