The investigation of the possibility for using some wild and cultivated plants as hyperaccumulators of heavy metals from contaminated soil

详细信息    查看全文

• 作者：Miroslava Maric (1)
  Milan Antonijevic (2)
  Sladjana Alagic (2)
  
• 关键词：Phytoremediation ; Heavy metals ; Contaminated soil ; Wild plants ; Cultivated plants ; Hyperaccumulators
• 刊名：Environmental Science and Pollution Research
• 出版年：2013
• 出版时间：February 2013
• 年：2013
• 卷：20
• 期：2
• 页码：1181-1188
• 全文大小：157KB
• 参考文献：1. Allen SE (1989) Chemical analysis of ecological material, 2nd edn. Blackwell, London
  2. Angle JS, Linacre NA (2005) Metal phytoextraction—a survey of potential risks. Int J Phytoremed 7:241-54 CrossRef
  3. Antonijevic M, Maric M (2008) Determination of the content of heavy metals in pyrite contaminated soil and plants. Sensors 8:5857-865 CrossRef
  4. Baker AJM, Brooks RR (1989) Terrestrial higher plants which hyperaccumulate metallic elements—a review of their distribution. Ecol Phytochem Biorecover 1:81-26
  5. Baker AJM, Walker PL (1990) Ecophysiology of metal uptake by tolerant plants. In: Shaw AJ (ed) Heavy metal tolerance in plants: evolutionary aspects. Boca Raton, CRC, pp 155-77
  6. Black J (1995) Absorbing possibilities: phytoremediation. Environ Heal Perspect 103:1106-108 CrossRef
  7. Cunningham SD, Ow DW (1996) Promises and prospects of phytoremediation. Plant Physiol 110:715-19
  8. Cunningham SD, Berti WR, Huang JW (1995) Phytoremedation of contaminated soils. Trend Biotechnol 13:393-97 CrossRef
  9. Denys S, Rollin C, Guillot F, Baroudi H (2006) In situ phytoremediation of PAHs contaminated soils following a bioremediation treatment. Water Air Soil Pollut Focus 6:299-15 CrossRef
  10. Dickinson NM, Baker AJM, Doronila A, Laidlaw S, Reeves RD (2009) Phytoremediation of inorganics: realism and synergies. Int J Phytoremediat 11:97-14 CrossRef
  11. ECCE, Element Concentration Cadasters in Ecosystems (1994) Progress report, presented at the 25th General Assembly of International Union of Biological Sciences, Paris
  12. French CJ, Dickinson NM, Putwain PF (2006) Woody biomass phytoremediation of contaminated brownfield land. Environ Pollut 141:387-95 CrossRef
  13. Gupta VK, Rastogi A (2008) Equilibrium and kinetic modelling of cadmium (II) biosorption by nonliving algal biornass / Oedogonium sp. from aqueous phase. J Hazard Mater 153(1-):759-66 CrossRef
  14. Gupta VK, Rastogi A (2009) Biosorption of hexavalent chromium by raw and acid-treated green alga / Oedogonium hatei from aqueous solutions. J Hazard Mater 163(1):396-02 CrossRef
  15. Gupta VK, Mittal A, Jain R, Mathur M, Sikarwar S (2006a) Adsorption of Safranin-T from wastewater using waste materials-activated carbon and activated rice husks. J Colloid Interface Sci 303(1):80-6 CrossRef
  16. Gupta VK, Mittal A, Gajbe V, Mittal J (2006b) Removal and recovery of the hazardous azo dye acid orange 7 through adsorption over waste materials: bottom ash and de-oiled soya. Ind Eng Chem Res 45(4):1446-453 CrossRef
  17. Gupta VK, Jain R, Varshney S (2007) Removal of Reactofix golden yellow 3 RFN from aqueous solution using wheat husk-An agricultural waste. J Hazard Mater 142(1-):443-48 CrossRef
  18. Hagemeyer J (2004) Ecophysiology of plant growth under heavy metal stress. In: Prasad MNV (ed) Heavy metal stress in plants: from molecules to ecosystems, 2nd edn. Springer, Berlin, pp 201-22
  19. Jones JB (2005) Hydroponics: a practical guide for the soilless grower, 2nd edn. CRC, Boca Raton
  20. Kabata-Pendias A, Dudka S (1991) Baseline data for cadmium and lead in soils and some cereals of Poland. Water Air Soil Poll 57(58):723-31 CrossRef
  21. Kinnersely AM (1993) The Role of phytochelates in plant growth and productivity. Plant Growth Regul 12:207-17 CrossRef
  22. Koeppe DE (1981) Lead: understanding the minimal toxicity of lead in plants. In: Lepp NW (ed) Effects of trace metals on plant function. Applied Science, New York, pp 55-6 CrossRef
  23. Kubota H, Takenaka C (2003) Arabis gemmifera is a hyperaccumulator of Cd and Zn. Int J Phytoremed 5(3):197-01 CrossRef
  24. Lai HY, Chen ZS (2004) Effects of EDTA on solubility of cadmium, zinc, and lead and their uptake by rainbow pink and vetiver grass. Chemosphere 55:421-30 CrossRef
  25. Lai HY, Chen ZS (2006) The effects of cadmium, zinc, and lead interactions on the accumulation of metals by rainbow pink. J Hazard Mater 137:1710-718 CrossRef
  26. Long XX, Yang XE, Ni WZ (2002) Current situation and prospect on the remediation of soils contaminated by heavy metals. Chin J Appl Ecol 13(6):757-62
  27. Lu S, Du Y, Zhong D, Zhao B, Li X, Xu M, Li Z, Luo Y, Yan J, Wu L (2012) Comparison of trace element emissions from thermal treatments of heavy metal hyperaccumulators. Environ Sci Technol 46:5025-031 CrossRef
  28. Maiz I, Esnaola V, Mill’an E (1997) Evaluation of heavy metal availability in contaminated soils by a short sequential extraction procedure. Sci Total Environ 206:107-15
  29. Maric M, Antonijevic M, Milutinovic S, Stevanovic D (2002) The effects of amelioration of the material content of heavy metals in soil damaged tailing. Proceedings of Safe food, Eco-Conference 125-29 (in Serbian)
  30. Mench M, Schwitzguébel JP, Schr?der P, Bert V, Gawronski S, Gupta S (2009) Assessment of successful experiments and limitations of phytotechnologies: contaminant uptake, detoxification and sequestration, and consequences for food safety. Environ Sci Pollut Res 16:876-00 CrossRef
  31. Mench M, Lepp N, Bert V, Schwitzguébel JP, Gawronski SW, Schr?der P, Vangronsveld J (2010) Successes and limitations of phytotechnologies at field scale: outcomes, assessment and outlook from COST Action 859. J Soils Sediments 10:1039-070 CrossRef
  32. Milijic Z (1997) The effects of amelioration of the material content of heavy metals in soil damaged tailing. Proceedings of Safe Food, Eco-Conference 125-29 (in Serbian)
  33. Milutinovic S, Zdravkovic M, Stamenkovic-Jovanovic S (1994) The possibility of recultivation of damaged soil pyrite tailings. II Scientific Conference on Natural Resources and Environmental Protection. Proceedings 21 (in Serbian)
  34. Milutinovic S, Petrovic R, Maric M (1997) Contribution to the study of repair of damaged soil pyrite tailings. Our ecological truth—proceedings 72-6 (in Serbian)
  35. Milutinovic S, Maric M, Aleksic V (1998) Recultivation of soil damaged by pyritic slag. Summaries of 16th Word Congress of Soil Science, Montpeliier France, vol II: 699
  36. Ouzounidou G (1994) Copper-induced changes on growth metal content and photosynthetic function of / Alyssum montanum L. plants. Environ Exp Bot 34:165-72 CrossRef
  37. Popovic Z (1987) Physiology of plants. Scientific literature: Belgrade (in Serbian)
  38. Raskin I, Kumar NPBA, Dushenkov S, Salt DE (1994) Bioconcentration of heavy metals by plants. Curr Opin Biotechn Env Bio 5:285-90 CrossRef
  39. Raskin I, Smith RD, Salt DE (1997) Phytoremediation of metals using plants to remove pollutants from the environment. Curr Opin Biotechnol 8:221-26 CrossRef
  40. Ross MS (1994) Sources and form of potentially toxic metals in soil-plant systems. In: Ross MS (ed) Toxic metals in soil–plant systems. Wiley, Chichester, pp 3-5
  41. Salt DE, Blaylock M, Kumar NPBA, Dushenkov V, Ensley BD, Chet I, Raskin I (1995) Phytoremediation: A novel strategy for removal of toxic metals from the environment using plants. Biotechnology 13:468-74 CrossRef
  42. Salt DE, Smith RD, Raskin I (1998) Phytoremediation. Annual Rev Plant Phys Plant Mol Biol 49:643-68 CrossRef
  43. Stevanovic D, Vukicevic O, Miranovic K (1995) Possibilities of biological cultivation of flotation tailings (Zn, Pb, Cu-sludge) in Mojkovac. Proceedings of Our Ecological truth, pp 83-4 (in Serbian)
  44. Sumner ME (1994) Measurement of soil pH: problems and solutions. Commun Soil Sci Plant Anal 25(7-):859-79 CrossRef
  45. Tandy S, Schulin R, Nowack B (2006) The influence of EDDS on the uptake of heavy metals in hydroponically grown sunflowers. Chemosphere 62:1454-463 CrossRef
  46. Wang X, Sato T, Xing B, Tao S (2005) Health risks of heavy metals to the general public in Tianjin, China via consumption of vegetables and fish. Sci Total Environ 350(1-3):28-7 CrossRef
  47. Westerman RL (1990) Soil testing and plant analysis. Soil Science Society of America, Madison, WI, 406
  
• 作者单位：Miroslava Maric (1)
  Milan Antonijevic (2)
  Sladjana Alagic (2)
  
  1. Faculty of Management in Zajecar, Park suma Kraljevica bb, 19200, Zajecar, Serbia
  2. Technical Faculty Bor, University of Belgrade, P.O.Box 50, 19210, Bor, Serbia
  
• ISSN：1614-7499

文摘

The copper production in Bor (East Serbia) during the last 100?years presents an important source of the pollution of environment. Dust, waste waters, tailing, and air pollutants influence the quality of soil, water, and air. Over 2,000?ha of fertile soil have been damaged by the flotation tailing from Bor’s facilities. The goal of the present work has been to determine the content of Pb, Cu, and Fe in wild plants (17 species) naturally growing in the damaged soil and in fodder crops (nine species) planted at the same place. The content of Pb, Cu, and Fe has been analyzed in damaged soil as well. This study has also searched for native (wild) and cultivated plants which are able to grow in contaminated soil in the area of the intense industrial activity of copper production in Bor, which means that they can accumulate and tolerate heavy metals in their above-ground tissues. It has been found out that the content of all metals in contaminated soil decreases considerably at the end of the experiment. As it has been expected, all plant species could accumulate investigated metals. All tested plants, both wild-growing and cultivated plants, seem to be quite healthy on the substrate which contained extremely high concentrations of copper.