|
|
|
| Research Progress on Phytoremediation to Polluted Environments by Mine Tailings in Arid Regions |
| He Mingzhu1, Hu Tianguang2, Cheng Binrang2, Chen Xiaohong2, Nie Kaihua2, Zhang Liuyi2, Cheng Shaoyi2 |
1. Shapotou Desert Research & Experiment Station, Cold and Arid Regions Environmental and Engineering Research Institute, Chinese Academy of Sciences, Lanzhou 730000, China;
2. Jinchuan Group LTD., Jinchang 737100, Gansu, China |
|
|
|
|
Abstract In arid regions, the ecological restoration process of mine land (in particular tailings and polluted environments) is, to a large extent, hampered by various natural disadvantages, such as water shortages, infertile soil, salinization and the relative scarcity of plant resources. Based on the relative studies carried out in polluted environments at home and abroad, this paper present a preliminary review of the theory and technology to phytoremediation which focused on comparative analysis of plant extracts and plant stable technologies and provided an analysis of typical application examples, and previewed the research and technology to pollution control in arid regions.
|
|
Received: 09 July 2013
Published: 20 September 2014
|
|
|
[1] Warhurst A.Mining, mineral processing,and extractive metallurgy:an overview of the technologies and their impact on the physical environment[M]//Warhurst A,Noronha L.Environmental Policy in Mining:Corporate Strategy and Planning for Closure.London,UK:CRC Press LLC,2000.
[2] Munshower F F.Practical Handbook of Disturbed Land Revegetation[M].London,UK:Lewis Publishing,1994.
[3] Li M S.Ecological restoration of mineland with particular reference to the metalliferous mine wasteland in China:a review of research and practice[J].Science of the Total Environment,2006,357:38-53.
[4] 宗和.一万余座,中国尾矿库安全吗?[J].地质勘察导报,2008,5:1-2
[5] Ye Z H,Shu W S,Zhang Z Q,et al.Evaluation of major constraints to revegetation of lead/zinc mine tailings using bioassay techniques[J].Chemosphere,2002,47:1103-1111.
[6] Bradshaw A D,Humphreys M O,Johnson M S.The Value of Heavy Metal tolerance in the revegetation of metalliferous mine wastes[M]//Goodman G T,Chadwick M J.Environmental Management of Mineral Wastes.Netherlands:Sijthoff & Noordhoff,1978:311-314.
[7] 廖晓勇,陈同斌,武斌,等.典型矿业城市的土壤重金属分布特征与复合污染评价——以“镍都”金昌市为例[J].地理研究,2006,25(5):843-852.
[8] Stevenson F J,Cole M A.Cycles of Soil:Carbon,Nitrogen,Phosphorus,Sulfur,Micronutrients[M]//New York,USA:John Wiley & Sons,Inc.,1999.
[9] Moynahan O S,Zabinski C A,Gannon J E.Microbial community structure and carbon-utilization diversity in a mine tailings revegetation study[J].Restoration Ecology,2002,10:77-87.
[10] Mendez M O,Glenn E P,Maier R M.Phytostabilization potential of quailbush for mine tailings:growth,metal accumulation,and microbial community changes[J].Journal of Environmental Quality,2007,36:245-253.
[11] 杨根生.尾矿砂沙害形成机理与工程治理措施的选择[J].中国沙漠,1997,17(4):435-441.
[12] Castro-Larragoitia J,Kramar U,Puchelt H.200 years of mining activities at La Paz,San Luis Potosi,Mexico-consequences for environment and geochemical exploration[J].Journal of Geochemical Exploration,1997,58:81 91.
[13] USEPA (US Environmental Protection Agency).Test Methods for Evaluating Solid Waste[R].EPA SW-846.US Government Print Office,Washington:2004.
[14] Neal C,Whitehead P G,Jeffery H,et al.The water quality of the River Carnon,west Cornwall,November 1992 to March 1994:the impacts of Wheal Jane discharges:bioremediation of acid Mine drainage:the Wheal Jane Mine Wetlands Project[J].Science of the Total Environment,2005,338:23-39.
[15] Madejon E,de Mora A P,Felipe E,et al.Soil amendments reduce trace element solubility in a contaminated soil and allow regrowth of natural vegetation[J].Environmental pollution,2006,139:40 52.
[16] Berti W W R,Cunningham S D.Phytostabilization of metals[M]//Raskin I,Ensley B D.Phytoremediation of Toxic Metals-Using Plants to Clean up the Environment.New York,USA:John Wiley & Sons,Inc.,2000:71-88.
[17] Wolfe A K,Bjornstad D J.Why would anyone object? an exploration of social aspects of phytoremediation acceptability[J].Critical Reviews in Plant Sciences,2002,21:429-438.
[18] Cunningham S D,Berti W R,Huang J W W.Phytoremediation of contaminated soils[J].Trends in Biotechnology,1995,13:393-397.
[19] Tordoff G M,Baker A J M,Willis A J.Current approaches to the revegetation and reclamation of metalliferous mine wastes[J].Chemosphere,2000,41:219-228.
[20] Whiting S N,Reeves R D,Richards D,et al.Research priorities for conservation of metallophyte biodiversity and their potential for restoration and site remediation[J].Restoration Ecology,2004,12:106-116.
[21] Pilon-Smits E A H,Freeman J L.Environmental cleanup using plants:biotechnological advances and ecological considerations[J].Frontiers in Ecology and the Environment,2006,4:203-210.
[22] Rosario K,Iverson S L,Henderson D A,et al.Bacterial community changes during plant establishment at the San Pedro River mine tailings site[J].Journal of Environmental Quality,2007,36:1249-1259.
[23] Piha M I,Vallack H W,Michael N,et al.A low input approach to vegetation establishment on mine and coal ash wastes in semiarid regions.2.Lagooned pulverized fuel ash in Zimbabwe[J].Journal of Applied Ecology,1995,32:382-390.
[24] Jordan F L,Robin-Abbott M,Maier R M,et al.A comparison of chelator-facilitated metal uptake by a halophyte and a glycophyte[J].Environmental toxicology and chemistry,2002,21:2698-2704.
[25] Smith R A H,Bradshaw A D.Stabilization of toxic mine wastes by the use of tolerant plant populations[J].Transaction of the Institution of Mining and Metallurgy(Section A),1972,81:230-237.
[26] Brooks R R.Plants that Hyperaccumulate Heavy Metals:Their Role in Phytoremediation,Microbiology,Archaeology,Mineral Exploration and Phytomining[M].Wallingford:CAB International,1998.
[27] Baker A J M,McGrath S P,Reeves R D,et al.Metal Hyperaccumulator Plants:A review of the ecology and physiology of a biological resource for phytoremediation of metal-polluted soils[M]//Terry N,Ban uelos G.Phytoremediation of Contaminated Soil and Water.Boca Raton,USA:Lewis Publishers,2000.
[28] Turnau K,Henriques F S,Anielska T,et al.Metal uptake and detoxification mechanisms in Erica andevalensis growing in a pyrite mine tailing[J].Environmental and Experimental Botany,2007,61:117-123.
[29] Deng J C,Liao B,Ye M,et al.The effects of heavy metal pollution on genetic diversity in zinc/cadmium hyperaccumulator Sedum alfredii populations[J].Plant and Soil,2007,297:83-92.
[30] Zhao F J,Lombi E,McGrath S P.Assessing the potential for zinc and cadmium phytoremediation with the hyperaccumulator Thlaspi caerulescens[J].Plant and Soil,2003,249:37-43.
[31] Knight B,Zhao F J,McGrath S P,et al.Zinc and cadmium uptake by the hyperaccumulator Thlaspi caerulescens in contaminated soils and its effects on the concentration and chemical speciation of metals in soil solution[J].Plant and Soil,1997,197:71-78.
[32] Meerts P,Van Isacker N.Heavy metal tolerance and accumulation in metallicolous and non-metallicolous populations of Thlaspi caerulescens from continental Europe[J].Plant Ecology.1997,133:221-231.
[33] Salt D E,Pickering I J,Prince R C,et al.Metal accumulation by aquacultured seedlings of Indian mustard.Environment Science & Technology,1997,31:1636-1644.
[34] Bennett L E,Burkhead J L,Hale K L,et al.Analysis of transgenic Indian mustard plants for phytoremediation of metal-contaminated minetailings[J].Journal of Environmental Quality,2003,32:432-440
[35] 孔令韶,孙世洲,罗金铃,等.青海锡铁山矿区铅、锌的植物地理化学特征及其与矿的关系[J].植物生态学与地植物学学报,1988,1(1):40-50.
[36] 宋慈安,雷良奇,杨启军,等.甘肃公婆泉铜矿区植物地球化学特征[J].地球化学,2000,29(4):343-350.
[37] 廖晓勇,陈同斌,闫秀兰,等.金昌镍铜矿区植物的重金属含量特征与先锋植物筛选[J].自然资源学报,2007,22(3):486-495.
[38] Krzaklewski W,Pietrzykowski M.Selected physicochemical properties of zinc and lead ore tailings and their biological stabilization[J].Water,Air & Soil Pollution,2002,141:125-142.
[39] Wu J,Hsu F C,Cunningham S D.Chelate-assisted Pb phytoextraction:Pb availability,uptake,and translocation constraints[J].Environment Science and Technology,1999,33:1898-1904.
[40] Schmidt U.Enhancing phytoextraction:the effect of chemical soil manipulation on mobility,plant accumulation,and leaching of heavy metals[J].Journal of Environmental Quality,2003,32:1939-1954.
[41] Wolfenbarger L L,Phifer P R.The ecological risks and benefits of genetically engineered plants[J].Science,2000,290:2088-2093.
[42] Pilon-Smits E,Pilon M.Phytoremediation of metals using transgenic plants[J].Critical Reviews in Plant Sciences,2002,21:439.
[43] Snow A A,Andow D A,Gepts P,et al.Genetically engineered organisms and the environment:current status and recommendations[J].Ecological Applications,2005,10:377-404.
[44] Conesa H M,Faz A,Arnaldos R.Heavy metal accumulation and tolerance in plants from mine tailings of the semiarid Cartagena-La Union Mining District (SE Spain)[J].Science of the Total Environment,2006,366:1-11.
[45] Del Rio-Celestino M,Font R,Moreno-Rojas R,et al.Uptake of lead and zinc by wild plants growing on contaminated soils[J].Industrial Crops and Products,2006,24:230-237.
[46] Conesa H M,Robinson B H,Schullin R,et al.Growth of Lygeum spartum in acid mine tailings:response of plants developed from seedlings,rhizomes,and at field conditions[J].Environmental pollution,2007,145:700-707.
[47] Fre rot H,Lefe`bvre C,Gruber W,et al.Specific interactions between local metallicolous plants improve the phytostabilization of mine soils[J].Plant and Soil,2006,282:53-65.
[48] Marschner H.Mineral Nutrition of Higher Plants[M].San Diego,USA:Academic Press Inc.,1995.
[49] Osmond C B,Bjorkman O,Anderson D J.Physiological Processes in Plant Ecology:Toward a Synthesis with Atriplex[M].New York,USA:Springer-Verlag,1980.
[50] Lutts S,Lefevre I,Delperee C,et al.Heavy metal accumulation by the halophyte species Mediterranean saltbush[J].Journal of Environmental Quality,2004,33:1271-1279.
[51] Ernst W H O.Phytoextraction of mine wastes-options and impossibilities[J].Chemie der Erde-Geochemistry,2005,65(S1):29-42.
[52] Keller C,Hammer D,Kayser A,et al.Root development and heavy metal phytoextraction efficiency:comparison of different plant species in the field[J].Plant and Soil,2003,249:67-81.
[53] Audet P,Charest C.Heavy metal phytoremediation from a meta-analytical perspective[J].Environmental Pollution,2007,147:231-237.
[54] Wong M H.Ecological restoration of mine degraded soils,with emphasis on metal contaminated soils[J].Chemosphere,2003,50:775-780.
[55] Glick B R.Phytoremediation:synergistic use of plants and bacteria to clean up the environment[J].Biotechnology Advances,2003,21:383-393.
[56] Conesa H M,Garcia G,Faz A,et al.Dynamics of metal tolerant plant communities development in mine tailings from the Cartagena-La Union Mining District (SE Spain) and their interest for further revegetation purposes[J].Chemosphere,2007,68:1180-1185.
[57] Johansson L,Xydas C,Messios N,et al.Growth and Cu accumulation by plants grown on Cu containing mine tailings in Cyprus[J].Applied Geochemistry,2005,20:101-107.
[58] Gonzalez R C,Gonzalez-Chavez M C A.Metal accumulation in wild plants surrounding mining wastes:soil and sediment remediation (SSR)[J].Environmental Pollution,2006,144:84-92.
[59] Flores-Tavizon E,Alarcon-Herrera M T,Gonzalez-Elizondo S,et al.Arsenic tolerating plants from mine sites and hot springs in the semi-arid region of Chihuahua,Mexico[J].Acta Biotechnology,2003,23:113-119.
[60] 赵磊.白音诺尔铅锌矿铅超富集植物筛选及其耐性研究[D].呼和浩特:内蒙古农业大学,2009.
[61] 冯宜民,何明珠,徐向宏,等.金川尾矿库土壤与植物重金属富集特征[J].水土保持学报,2011,25(5):177-181.
[62] Bech J,Poschenrieder C,Barcelo J,et al.Plants from mine spoils in the South American area as potential sources of germplasm for phyotremediation technologies[J].Acta Biotechnology,2002,1 2:5 11.
[63] Jefferson LV.Implications of plant density on the resulting community structure of mine site land[J].Restoration Ecology,2004,12:429-438.
[64] Sabey B R,Pendleton R L,Webb B L.Effect of municipal sewage-sludge application on growth of two reclamation shrub species in copper mine spoils[J].Journal of Environmental Quality,1990,19:580-586.
[65] Windsor D M,Clements A.A germination and establishment field trial of Themeda australis (kangaroo grass) for mine site restoration in the Central Tablelands of New South Wales[J].Restoration Ecology,2001,9:104-110.
[66] Mummey D L,Stahl P D,Buyer J S.Soil microbiological properties 20 years after surface mine reclamation:spatial analysis of reclaimed and undisturbed sites[J].Soil Biology and Biochemistry,2002,34:1717-1725.
[67] Tilman D.Plant Strategies and the Dynamics and Structure of Plant Communities[M].New Jersey,USA:Princeton University Press,1988.
[68] Gebauer R L E,Ehleringer J R.Water and nitrogen uptake patterns following moisture pulses in a cold desert community[J].Ecology,2000,81:695-712.
[69] Watson I W,Westoby M,Holm A M.Continuous and episodic components of demographic change in arid zone shrubs:models of two Eremophila species from Western Australia compared with published data on other species[J].Journal of Ecology,1997,85:833-846.
[70] Castellanos A E,Martinez M J,Llano J M,et al.Successional trends in Sonoran Desert abandoned agricultural fields in northern Mexico[J].Journal of Arid Environments,2005,60:437-455.
[71] Pierzynski G M,Lambert M,Hetricck B A D,et al.Phytostabilization of metal mine tailings using tall fescue[J].Journal of Hazardous,Toxic,and Radioactive Waste,2002,6:212-217.
[72] Pond A P,White S A,Milczarek M,et al.Accelerated weathering of biosolid-amended copper mine tailings[J].Journal of Environmental Quality,2005,34:1293-1301.
[73] Mains D,Craw D,Rufaut C G,et al.Phytostabilization of gold mine tailings from New Zealand.Part 2:experimental evaluation of arsenic mobilization during revegetation[J].International Journal of Phytoremediation,2006,8:163-183.
[74] Lottermoser B G,Ashley P M,Costelloe M T.Contaminant dispersion at the rehabilitated Mary Kathleen uranium mine,Australia[J].Environmental Geology,2005,48:748-761. |
| No Suggested Reading articles found! |
|
|
Viewed |
|
|
|
Full text
|
|
|
|
|
Abstract
|
|
|
|
|
Cited |
|
|
|
|
| |
Shared |
|
|
|
|
| |
Discussed |
|
|
|
|
2014, Vol. 34 
