环境污染治理领域中的植物修复技术

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Abstract

Phytoremediation has a strong potential as a natural, solar-energy driven remediation approach for the treatment of sites, groundwater and wastewater contaminated with various chemicals. The basic mechanism of phytoremediation is the use of green plants natural abilities to remove, contain, inactivate, or degrade constituents of contaminated media. It is inexpensive, effective and green. A special advantage of phytoremediation compared to other treatment methods is that soil functioning is maintained and life in soils is reactivated. In this paper, heavy emphasis is placed on the discussion of relevant processes and existing uncertainties in phytoremediation. This article also intends to give an overview of current development, and an insight into methods and application. A number of external and internal factors are involved in the field application and its basic mechanisms are still under development, so the reality of phytoremediation as an in-situ technique is very different to evaluate. In conclusion, full understanding of phytoremediation would require a more comprehensive study than as it was done in this report.

Key words： Contamination Environment Phytoremediation Plants

Received: 25 June 2004

PACS:

X173

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	YU Xiaozhang

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YU Xiaozhang. Aeview of phytoremediation as a treatment technique for cleaning contaminated environmental media[J]. , 2004, 23(3): 256-260.

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http://journal15.magtechjournal.com/Jwk_stkx/EN/ OR http://journal15.magtechjournal.com/Jwk_stkx/EN/Y2004/V23/I3/256

[1] Cunninggham S D, and Ow D W. 1996. Promises and prospects of phytoremediation[J]. Plant Physiology, 110(3):715-719.

[2] Schwitzguebei J P. 2001. Hype or Hope: the potential of phytoremediation as an emerging green technology[J].Remediation, 11(4) 63-78.

[3] Zhang Q L, Davis C, Erickson L E. 1999. An experimental study of phytoremediation of MTBE in ground water. [A] In:Erickson L E (ed). Proceedings of the 1999 Conference on Hazardous Waste Research[C]. Manhanttan: Kansas State University. 227-242.

[4] Flathman P E, Lanza G R. 1998. Phytoremediation current views on an emerging green technology[J]. Journal of Soil Contamination, 7(6): 415-432.

[5] Schnoor J L, Licht L A, McCutcheon S C, et al. 1995.Phytoremediation of organic and nutrient contaminants[J].Environmental Science & Technology, 29(7): 318-323.

[6] Cunninggham S D, Anderson T A, Schwab A P et al. 1996.Phytoremediation of soils contaminated with organic polluants[J]. Advances in Agronomy. 56 (1):55-114.

[7] Vangronsveld J, Colpaert J, Van Tichelen K. 1996.Reclamation of brace industrial area contamianted with non-ferrous metals: Physico-chemical and biological evaluation of the durability of soil treatment and revegetation[J]. Environmental Pollution, 94 (2):131-140.

[8] Tibazarwa C, Corbisier P, Mench M, et al. 2001. A microbial biosensor in bioremediaton to predict bioavailable nickle in soil and its transfer to plants[J]. Environmental Pollution, 113 (1): 19-26.

[9] Alexander M, Hatzinger P B, Kelsey J W, et al., 1997.Sequestration and realistic risk from toxic chemicals remaining after bioremediation[J]. Annals New York Academy of Sciences, 829 (11):59-76.

[10] Vance D B. 1996. Phytoremediation: enhancing natural attenuation processes[J]. National Environmental Journal,6(1):30-31.

[11] Wright A L, Weaver R W, Webb J W. 1997. Oil bioremediation in salt marsh mesocosms as influenced by N and P fertilization, flooding, and season[J]. Water, Air and Soil Pollution, 95 (3): 170-191.

[12] Carmichael L M, Pfaender F K. 1997. Polynuclear aromatic hydrocarbon metabolism in soils: relationship to soil characteristics and preexposure[J]. Environmental Toxicology and Chemistry. 16(4): 892-899.

[13] McConkey B J, Duxbury C L, Dixon D G, et al. 1997.Toxicity of a PAH photooxidation product to the bacteria Photobacterium phosphoreum and the duckweed Lemna gibba: effects of phenanthrene and its primary photoproduct,phenanthrenequinone[J]. Environmental Toxicology and Chemistry. 16(5): 666-675.

[14] McCutcheon S C, Rock S A. 2001. Phytoremediation: state of the science conference and other developments[J].International Journal of Phytoremediation, 3(1): 1-11.

[15] US EPA Environment Protect Agency. 2000. Introduction to phytoremediation[M]. Cincinnati: EPA eport-600-R-99-107(Office of Research and Development), U.S Government Printing Offic, Ohio. 86-94.

[16] Schwizguebel J P, Lelie D, Baker A, et al. 2002.Phytoremediation: European and American trends(Successes, obstacles and needs)[J]. Journal of Soils &Sediments, 2(2):91-99.

[17] Newman L A, Doty S L, Gery K L, et al. 1998.Phytoremediation of organic contaminants:a review of phytoremediation research at the University of Washington[J]. Journal of Soil Contamination, 7(6):531-542.

[18] Watanabe M E. 1997. Phytoremediation on the brink of commercialization[J]. Environmental Science & Technology,31(Ⅰ):182-186.

[19] Siciliano S D and Germida J J. 1998. Mechanisms of phytoremediation: biochemical and eco logical interactions between plants and bacteria[J]. Ennvironmental Review,6(1):65-79.

[20] Radwan S S, Al-Awadhi H, Sorkhoh N, et al. 1998.Rhizospheric hydrocarbon-utilizing microorganisms as potential contributors to phytoremediation for the oily Kuwait desert[J]. Microbiological Research. 153(3):247-251.

[21] Matthis M and Behrendt H. 1995. Dynmices of leaching,uptake, and translocation: The simulation network atmosphere-plant-soil (SNAPS). In Trapp S, Mc Farlane C(Ed). Plant Contamination-Modeling and Simulation of Organic Chemicals Processes[M]. Boca Raton: Lewis Pub.,Floride, USA.215-243.

[22] Black H. 1999. Phytoremediation: a growing field with some concerns[J]. The Scientist, 13(3): 5-6.

[23] Sandermann H. 1994. Higher plant metabolism of xenobiotics:the 'green liver' concept[J]. Pharmacogenetics,4 (3):225-241.

[24] Komossa D, Langebartels C, Sandermann H. 1995.Metabolic processes for organic chemicals in plants. In Trapp S, Mc Farlane C (Ed). Plant Contamination-Modeling and Simulation of Organic Chemicals Processes[M]. Boca Raton: Lewis Pub., Floride, USA, 69-103.

[25] Maruyama A, Saito K, and Ishizawa K. 2001.β-cyanoalanine synthase and cysteine synthase from potato:molecular cloning, biochemical characterization, and spatial and hormonal regulation[J]. Plant Molecular Biology, 46(1):749-760.

[26] Hendrickson HR and Conn EE. 1969. Cyanide metabolism in higher plants. Puriification and properties of theβ-cyanoalanine synthase of blue lupine[J]. Journal of Biological Chemistry, 244(3): 2632-2640.

[27] Newman L A, Wang X, Muiznieks Ⅰ, et al. 1999..Remediation of trichloroethylene in an artificial aquifer with trees: A controlled field study[J]. Environmental Science & Technology, 33(12):2257-2265.

[28] Fletcher J S. 1990. Use of algae versus vascular plants to test for chemical toxicity. In: Wang W, Gorsuch J W, Lower W R, (Ed). Plants for Toxicity Assessment[M]. Philadelphia:ASTM STP 1091 American Society for Testing and Materials, USA, 33-39.

[29] Trapp S, Christiansen, H. 2003. Phytoremediation of cyanide-polluted soils. In: McCutcheon, S.C., Schnoor, J.L.(Eds). Phytoremediation: Transformation and Control of Contaminants[M]. Hoboken: John Wiley & Sons, New Jersey, USA, 829-862.

[30] Doty S L, Shang T Q, Wilson A M, et al. 2000. Enhanced metabolism of helogenated hydrocarbons in transgenic plants containing mammalian cytochrome P450 2El[J].Proceedings of the National Academy of Sciences, USA., 97(10):6287-6291.

[31] Office of Technology Assessment (OTA). 1993. Harmful Non-indigenous Species in the United States[M].Washington: U. S Government Printing Office. 83-120.

[32] Dobson M C, and Moffat A J. 1995. A re-evaluation of objections to tree planting on contaminated landfills[J].Waste Management & Research, 13(6):579-600.

[33] Burken J G, and Schnoor J L. 1996. Phytoremediation: Plant uptake of atrazine and role of root exudates[J]. ASCE Journal of Envirmental Engineering, 122 (12):958-963.

[34] Romantschuk M, Sarand I, Petanen T, et al. 2000. Means to improve the effect of in-situ bioremediation of contaminated soil:an overview of novel approaches[J]. Environmental Pollution, 107 (3): 179-185.

[35] Grosse W, Jovy K, Tiebel H. 1996 Influencee of plants on redox-potential and methance production in water-saturated soil [J]. Hydrobiologica, 340 (1):93-99.

[36] Reynolds C M, Wold D C, Gentry T J, et al. 1999. Plant enhancement of indigenous soil micro-organisms: a low-cost treatment of contamianted soils[J]. Poplar Record,35(1):33-40.

[37] Hulster A, Muller J F, Marschner H. 1994. Soil-plant tranfer of polychorinated dibenzo-p-dioxins and dibenzofurans to vegetables of the cucumber family (Cucurbitaceae)[J].Environmental Science & Technology, 28(6): 1110-1115.

[38] Hong M S, Farmayan W F, Dortch Ⅰ J, et al. 2001.Phytoremediation off MTBE from a groundwater plume.Environmental Science and Technology, 35(6): 1231-1239.

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