Phytoremediation of metal contaminated mining sites

International Journal of Earth Sciences and Engineering

Volumn 5, Issue 3, 2012, Pages 428-436

  Sheoran, V ^a   Sheoran, A S ^a   Poonia, P ^a  

^a JAI NARAIN VYAS UNIVERSITY   (India)

Author keywords

Metal Contaminated Mining Site; Phytoextraction; Phytoremediation; Phytostabilization

Indexed keywords

ALTERNATIVE TECHNOLOGIES; BASIC CONCEPTS; CONTAMINATED SOILS; CONVENTIONAL METALS; ENVIRONMENTAL TOXINS; ENVIRONMENTAL-FRIENDLY; METAL CONCENTRATIONS; METAL POLLUTION; MINE SPOIL; MINING ACTIVITIES; MINING SITES; PHYTOEXTRACTION; PHYTOREMEDIATION; PHYTOSTABILIZATION; PLANT COMMUNITIES; PLANT ORGANS; REMEDIAL TECHNOLOGY; SOIL FERTILITY; WASTE ROCKS;

BIOREMEDIATION; CONTAMINATION; ECOSYSTEMS; HEAVY METALS; METALS; SOIL POLLUTION;

SOIL POLLUTION CONTROL;

BIOACCUMULATION; HEAVY METAL; MINE WASTE; MINING; PHYTOREMEDIATION; PLANT; POLLUTANT REMOVAL; SOIL POLLUTION; SOIL REMEDIATION; TAILINGS;

EID: 84863755354     PISSN: 09745904     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Article

References (70)

1. Yang X., Feng Y., He Z., Stoffella P.J., (2005). Molecular mechanisms of heavy metal hyperaccumulation and phytoremediation, J. Trace Elem. Med. Biol., 18, 339-353.
2. Bradshaw A.D., (1997). Restoration of mined lands-using natural processes, Ecol. Eng., 8, 255-269.
3. Li M.S., (2005). Ecological restoration of mine land with particular reference to the metalliferous mine wasteland in China: A review of research and practice, Sci. Total Environ., 357, 38-53.
4. Knasmuller S., Gottmann E., Steinkellner H., Fomin A., Pickl C., Paschke A., God R., Kundi M., (1998). Detection of genotoxic effects of heavy metal contaminated soils with plant bioassay, Mutat. Res., 420 37-48.
5. Sheoran A.S., Sheoran V., Poonia P., (2008b). Rehabilitation of mine degraded land by metallophytes, Mining Eng. J., 10(3), 11-16.
6. Sheoran V., Sheoran A.S., Poonia P., (2008a). Remediation techniques for contaminated soils, Environ. Eng. Manage. J., 7(4), 379-387.
7. Lasat M.M., (2002). Phytoextraction of toxic metals: a review of biological mechanisms, Journal Environ. Qual., 31,109-120.
8. Wong M.H., (2003). Ecological restoration of mine degraded soil, with emphasis on metal contaminated soil, Chemosphere, 50, 775-780.
9. Sheoran V., Sheoran A.S., Poonia P., (2010). Soil management for reclamation of abandoned mine land by revegetation: a review, Int. J. Soil Sediment Water, 3(2), Article 13.
10. Barcelo J., Poschenrieder C., (2003). Phytoremediation: principles and perspectives, Contribution to Science, 2(3) 333-344.
11. Cunningham S.D., Shann J.R., Crowley D.E., Anderson T.A., (1997). Phytoremediation of contaminated water and soil, In Proceedings Phytoremediation of Soil and Water Contaminants, edited by E L Anderson, T A Coats & J R Kruger, ACS symposium series 664, Washington, DC, American Chemical Society, 2-19.
12. Baker A.J.M., Brooks R.R., (1989). Terrestrial higher plants which hyperaccumulate metal elements: A Review of their distribution, ecology, and phytochemistry, Biorecovery, 1, 81-126.
13. Reeves R.D., (2003). Tropical hyperaccumulators of metals and their potential for phytoextraction, Plant Soil, 249, 57-65.
14. Pollard A.J., Powell K.D., Harper F.A., Smith J.A.C., (2002).The genetic basis of metal hyperaccumulation in plants, Crit. Rev. Plant Sci., 21(6), 539-566.
15. Sheoran V., Sheoran A.S., Poonia P., (2009). Phytomining: A review. Miner. Eng., 22(12), 1007-1019.
16. Sheoran V., Sheoran A.S., Poonia P., (2011). Role of hyperaccumulators in phytoextraction of metals from contaminated mining sites: a Review, Crit. Rev. Environ. Sci. Technol., 41(2), 168-214.
17. do Nascimento C.W.A., Xing B., (2006). Phytoextraction a review on enhanced metal availability and plant accumulation, Scienta Agricola (Piracicaba, Brazil), 3(3), 299-311.
18. Khan A.G., (2005). Role of soil microbes in the rhizospheres of plants growing on trace metal contaminated soils in phytoremediation, J. Trace Elem. Med. Biol., 18, 355-364.
19. Meers E., Vandecasteele B., Ruttens A., Vangronsveld J, Tack F.M.G., (2007). Potential of five willow species (Salix spp.) for phytoextraction of heavy metals. Environ. Exp. Bot., 60, 57-68.
20. Kuffner M., Puschenreiter M., Wieshammer G., Gorfer M., Sessitsch A., (2008). Rhizosphere bacteria affect growth and metal uptake of heavy metal accumulating willows, Plant Soil, 304, 35-44.
21. Felix H.R.Z., (1997). Field trials for in situ decontamination of heavy metal polluted soils using crops of metal-accumulating plants, Z. Pflanzenernahr Bodenk, 160, 525-529.
22. Huang J.W., Cunningham S.D., (1996).Lead phytoextraction: species variation in lead uptake and translocation, New Phytol, 134, 75-84.
23. Evangelou M.W.H., Ebel M., Schaeffer A., (2007). Chelate assisted phytoextraction of heavy metals from soil-effect, mechanism, toxicity, and fate of chelating agents, Chemosphere, 68, 989-1003.
24. Thangavel P., Subhuram C.V., (2004). Phytoextraction- Role of hyperaccumulators in metal contaminated soils, Proceedings of the Indian National Science Academy Part: B 70(1), 109-130.
25. Cunningham S.D., Ow D.W., (1996). Promises and prospects of phytoremediation, Plant Physiology, 110(3), 715-719.
26. Robinson B., Fernandez J.E., Madejon P., Maranon T., Murillo J.M., Green S., Clothier B., (2003). Phytoextraction: an assessment of biogeochemical and economic viability, Plant and Soil, 249, 117-125.
27. Ginneken L.V., Meers E., Guisson R., Ruttens A., Elst K., Tack F.M.G., Vangronsveld J., Diels L., Dejonghe W., (2007). Phytoremediation for heavy metal contaminated soils combined with bioenergy production, J. Environ. Eng. Landscape Manage., 15(4), 227-236.
28. Anderson C., Moreno F., Meech J., (2005). A field demonstration of gold phytoextraction technology, Miner. Eng., 18, 385-392.
29. Pal R, Rai J P N, Phytochelatins: Peptides involved in heavy metal detoxification, Appl. Biochem. Biotechnol., 160 (2010) 945-963.
30. Rajkumar M., Ae N., Prasad M.N.V., Frietas H., (2010). Potential of siderophore-producing bacteria for improving heavy metal phytoextraction, TIBTEC, 781, 1-8.
31. Rajkumar M., Prasad M.N.V., Frietas H., Noriharu A., (2009). Biotechnological applications of serpentine soil bacteria for phytoremediation of trace metals, Crit. Rev. Biotechnol., 29, 120-130.
32. Kavamura V.N., Esposito E., (2010). Biotechnological strategies applied to the decontamination of soils polluted with heavy metals, Biotechnol. Adv., 28, 61-69.
33. Rascio N., Navari-Izzo F., (2011). Heavy metal hyperaccumulating plants: How and why do they do it? And what makes them so interesting? Plant Sci., 180,169-181.
34. Hassan Z., Aarts M.G.M., (2011). Opportunities and feasibilities for biotechnological improvement of Zn, Cd, or Ni tolerance and accumulation in plants, Environ. Exp. Bot., 72, 53-63.
35. Shu W.S., Lan C.Y., Zhang Z.Q., Wong M.H., 2000. Use of vetiver and other three grasses for revegetation of Pb/Zn mine tailings at Lechang, Guangdong Province: field.Experiment. In: Proceedings Second International Vetiver Conference Bangkok, Thailand, 58-68
36. Dahmani-Muller H., van Oort F., Gelie B., Balabane M., (2000). Strategies of heavy metal uptake by three plant species growing near a metal smelter, Environ. Pollut., 109, 231-238.
37. Freitas H., Prasad M.N.V., Pratas J., (2004). Plant community tolerant to trace elements growing on the degraded soils of Sao Domingos mine in south east of Portugal: environmental implications, Environ. Int., 30, 65-72.
38. Maiti S.K., Nandhini S., (2005). Bioremediation of Fe ore tailings and bioaccumulation of metals in the naturally occurring vegetation: A case of Noamundi Fe-ore tailings, TISCO, Noamundi, Int. seminar on Mineral Processing Technology (MPT-2005) Jan. 6-8,
39. Kidd P.S., Monterroso C., (2005). Metal extraction by Alyssum serpyllifolium ssp. Lusitanicum on mine-spoil soils from Spain, Sci. Total Environ., 336, 1-11.
40. Yanqun Z., Yuan L., Jianjun C., Haiyan C., Li Q., Schvartz C., (2005). Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead-zinc mining area in Yunnan, China, Environ. Int., 31, 755-762.
41. Gonzalez R.C., Gonzalez-Chavez M.C.A., (2006). Metal accumulation in wild plants surrounding mining wastes, Environ. Pollut., 1-9.
42. Liu Y.G., Zhang H.Z., Zeng G.M., Huang B.R., Li X., (2006). Heavy metal accumulation in plants on Mn mine tailings, Pedosphere, 16(1), 131-136.
43. Wang S.L., Liao W.B., Yu F.Q., Liao B., Shu W.S., (2009). Hyperaccumulation of lead, zinc, and cadmium in plants growing on a lead/zinc outcrop in Yunnan Province, China. Environ. Geol., 58, 471-476.
44. Salt D.E., Blaylock M., Kumar P.B.A.N, Dushenkov V., Ensley B.D., Chet I., Raskin I., (1995). Phytoremediation: A novel strategy for the removal of toxic metals from the environment using plants, Biotechnol., 13, 468-475.
45. Padmavathiamma P.K., Loretta Y.M., (2007). Phytoremediation technology: Hyperaccumulation metals in plants, Water Air Soil. Pollut., 184, 105-126.
46. Flathman P E & Lanza G R, Phytoremediation: current views on an emerging green technology, J. Soil Contam., 7(4) (1998) 415-432.
47. Mains D., Craw D., Rufaut C.G., Smith C.M.S., (2006). Phytostabilization of gold mine tailings, New Zealand. Part 1: Plant establishment in alkaline saline substrate, Int. J. Phytorem., 8(2), 131-147.
48. Clemente R., Almela C., Bernal P.M., (2006). A remediation strategy based on active phytoremediation followed by natural attenuation in a soil contaminated by pyrite waste, Environ. Pollut., 143(3), 397-406.
49. Watanabe T., Oski, M., (2002). Mechanisms of adaptation to high aluminum conditions in native plant species growing in acid soils: a review, Comm. Soil Sci. Plant Anal., 33, 1247-1260.
50. Kidd P., Barcelo J., Bernal M.P., Navari-Izzo F., Poschenrieder C., Shilev S., Clemente R., Monterroso C., (2009). Trace metal behavior at the root-soil interface: Implications in Phytoremediation, Environ. Exp. Bot., 67, 243-259.
51. Nies D.H., (2003). Efflux-mediated heavy metal resistance in prokaryotes, FEMS Microbiol. Ecol., 27,313-339.
52. Hindebrandt U., Regvar M., Bothe H., (2007). Arbuscular mycorrhiza and heavy metal tolerance, Phytochem., 68, 139-146.
53. Dupre de Boulois H., Joner E.J., Leyval C., Jakobsen I., Chen B.D., Roos P., Thiry Y., Rufyikiri G., Delvaux B., Declerck S., (2008). Impact of arbuscular mycorrhizal fungi on uranium accumulation in plants, J. Environ. Radioactivity, 99, 775-784.
54. Smith R.A.H., Bradshaw A.D., (1992). Stabilization of toxic mine wastes by the use of tolerant plant populations, Trans Inst. Min. Metall. Sect. A, 81, 230-237.
55. Yang Z.Y., Yuan J.G., Xin G.R., Chang H.T., Wong M.H., (1997). Germination, growth and nodulation of Sesbania rostrata grown in Pb/Zn mine tailings, Environ. Manage. 21, 617-622.
56. Zhang Z.Q., Shu W.S., Lan C.Y., Wong M.H., (2001). Soil seed bank as an input of seed sources in vegetation of lead/ zinc mine tailings, Restoration Ecol., 9, 1-8.
57. Madejon P., Murillo J.M., Maranon T., Cabrera F., Lopez R., (2002). Bioaccumulation of As, Cd, Cu, Fe, and Pb in wild grasses affected by the Aznalcollar mine spill, Sci. Total Environ., 290, 105-120.
58. Yang B., Shu W.S., Ye Z.H., Lan C.Y., Wong M.H., (2003). Growth and metal accumulation in vetiver and two Sesbania species on lead/zinc mine tailings, Chemosphere, 52, 1593-1600.
59. Conesa M.H., Faz A., Arnaldos R., (2006). Initial studies for the phytostabilization of a mine tailing from the Cartagena-La Union Mining District (SE Spain), Chemosphere, 66(1), 38-44.
60. Kramer P.A., Zabowski D., Scherer G., Everett R.L., (2000). Native plant restoration of copper mine tailings: I. Substrate effect on growth and nutritional status in a greenhouse study, J. Environ. Qual., 29, 1762-1769.
61. Mendez M.O., Glenn E.P., Maer R.M., (2007). Phytostabilization potential of quailbush for mine tailings: growth, metal accumulation, and microbial community changes, J. Environ. Qual., 36, 245-253.
62. Madejon P., Murillo J.M., Maranon T., Cabrera F., Soriano M.A., (2003). Trace element and nutrient accumulation in sunflower plants two year after the Aznalcollar mine spill, Sci Total Environ., 307, 239-257.
63. Song S.Q., Zhou X., Wu H., Zhou Y.Z., (2004). Application of municipal garbage compost on revegetation of tin tailings dams, Rural Eco- Environ, 20(2), 59-61.
64. Mertens J., Van Nevel L., De Schrijver A., Piesschaert F., Oosterbean A., Tack F.M.G., Verheyen K., (2007).Tree species effect on the redistribution of soil metals, Environ. Pollut., 149, 173-181.
65. Misra V., Tiwari A., Shukla B., Seth C.S., (2008). Effects of soil amendments on the bioavailability of heavy metals from zinc mine tailings, Environ. Monit. Assess., 155 (1-4), 467-75.
66. Zhou L.B., Dai H.W., Wu Y.J., Gao J.H., Ning Y.P., Wang Z.Y., (2002). Reclamation of copper mine tailings dams in Hujiaya using crops plantation, Mining Technol., 2(2), 54-56.
67. Hao X.Z., Zhou D.M., Wang Y.J., Chen H.M., (2004). Study of rye grass in copper mine tailing treated with peat and chemical fertilizer, Acta. Pedol. Sin., 41(4), 645-648.
68. Antosiewicz D.M., Escude-Duran C., Wierzbowska E., Sklodowska A., (2008). Indigenous plant species with the potential for the phytoremediation of arsenic and metal contaminated soil, Water Air Soil Pollut., 193, 197-210.
69. King D.J., Doronila A.I., Feenestra C., Baker A.J.M., Woodrow I.E., (2008).Phytostabilization of arsenal gold mine tailings using four Eucalytus species: Growth, arsenic uptake and availability after 5 years, Sci. Total Environ., 406(1-2), 35-42.
70. Martinez-Alcala I., Clemente R., Bernal M.P., (2009).Metal availability and chemical properties in the rhizosphere of Lupinus albus L. growing in a high-metal calcareous soil, Water Air Soil Pollut., 201, 283-293.