Remediation technologies for heavy metal contaminated groundwater

Journal of Environmental Management

Volumn 92, Issue 10, 2011, Pages 2355-2388

  Hashim, M A ^a   Mukhopadhyay, Soumyadeep ^a   Sahu, Jaya Narayan ^a   Sengupta, Bhaskar ^b  

^a UNIVERSITY OF MALAYA   (Malaysia)

^b QUEEN'S UNIVERSITY BELFAST   (United Kingdom)

Author keywords

Groundwater; Heavy metals; Remediation technology; Soil; Water treatment

Indexed keywords

AQUIFERS; BIOREMEDIATION; CONTAMINATION; ENVIRONMENTAL TECHNOLOGY; GROUNDWATER POLLUTION; GROUNDWATER RESOURCES; METAL RECOVERY; SITE SELECTION; SOIL POLLUTION; SOIL POLLUTION CONTROL; SOILS; SULFUR COMPOUNDS; SUSTAINABLE DEVELOPMENT; WATER TREATMENT;

ANTHROPOGENIC SOURCES; CLASSIFIEDS; CONTAMINATED GROUNDWATER; CONTAMINATION REMEDIATION; GROUNDWATER TREATMENT; NATURAL SOILS; PHYSICOCHEMICAL TREATMENTS; REMEDIATION TECHNOLOGIES; SOIL SOURCES; TREATMENT PROCESS;

HEAVY METALS;

ACTIVATED CARBON; ARSENIC; BIOSURFACTANT; CADMIUM; CELLULOSE; CHELATE; CHROMIUM; COPPER; DITHIONITE; GROUND WATER; HEAVY METAL; IRON; LEAD; MAGNETITE; MERCURY; ORGANIC CARBON; RADIOISOTOPE; REDUCING AGENT; ZEOLITE; ZINC;

BIOCHEMICAL COMPOSITION; BIOREMEDIATION; DRINKING WATER; GROUNDWATER POLLUTION; HEALTH RISK; HEAVY METAL; HUMAN ACTIVITY; MICROBIAL ACTIVITY; PHYSICOCHEMICAL PROPERTY; PUBLIC HEALTH; SPATIAL ANALYSIS;

ABSORPTION; AGRICULTURAL WASTE; BIOLOGICAL ACTIVITY; BIOREMEDIATION; BIOSORPTION; DENITRIFICATION; FILTRATION; HEAVY METAL REMOVAL; INDUSTRIAL WASTE; ION EXCHANGE; PHYSICAL CHEMISTRY; PRECIPITATION; REVIEW; SLAG; SOIL; SOIL AMENDMENT; SOIL POLLUTION; SOIL TREATMENT; SULFATE REDUCING BACTERIUM; WATER CONTAMINATION;

EID: 79960838181     PISSN: 03014797     EISSN: 10958630     Source Type: Journal    
DOI: 10.1016/j.jenvman.2011.06.009     Document Type: Review

References (360)

1. Álvarez-Ayuso E., Nugteren H.W. Purification of chromium(VI) finishing wastewaters using calcined and uncalcined Mg-Al-CO3-hydrotalcite. Water Research 2005, 39:2535-2542.
2. January 2005, ARS Technologies Inc.
3. Abou-Shanab R.A.I., Angle J.S., Chaney R.L. Bacterial inoculants affecting nickel uptake by Alyssum murale from low, moderate and high Ni soils. Soil Biology and Biochemistry 2006, 38:2882-2889.
4. Abramovitch R.A., Huang B.Z., Davis M., Peters L. In situ remediation of soils contaminated with toxic metal ions using microwave energy. Chemosphere 2003, 53:1077-1085.
5. Acar Y.B., Alshawabkeh A. Principle of electrokinetic remediation. Journal of Environmental Science and Technology 1993, 27:2638-2647.
6. Acharya J., Sahu J.N., Mohanty C.R., Meikap B.C. Removal of lead(II) from wastewater by activated carbon developed from Tamarind wood by zinc chloride activation. Chemical Engineering Journal 2009, 149:249-262.
7. Acharya J., Sahu J.N., Sahoo B.K., Mohanty C.R., Meikap B.C. Removal of chromium(VI) from wastewater by activated carbon developed from Tamarind wood activated with zinc chloride. Chemical Engineering Journal 2009, 150:25-39.
8. Ahamed S., Hussam A., Munir A.K.M. Groundwater Arsenic Removal Technologies Based on Sorbents: Field Applications and Sustainability, Handbook of Water Purity and Quality 2009, Academic Press, Amsterdam, 379-417.
9. Ahn J.S., Chon C.M., Moon H.S., Kim K.W. Arsenic removal using steel manufacturing by-products as permeable reactive materials in mine tailing containment systems. Water Research 2003, 37:2478-2488.
10. Ajmal M., Rao R.A.K., Ahmad R., Ahmad J. Adsorption studies on Citrus reticulata (fruit peel of orange): removal and recovery of Ni(II) from electroplating wastewater. Journal of Hazardous Materials 2000, 79:117-131.
11. Allen S.J., Brown P. Isotherm analysis for single component and multi-component metal sorption onto lignite. Journal of Chemical Technology & Biotechnology 1995, 62:17-24.
12. Allen J.P., Torres I.G. Physical separation techniques for contaminated sediment. Recent Developments in Separation Science 1991, CRC Press, West Palm Beach, FL. N.N. Li (Ed.).
13. Allen S.J., Whitten L.J., Murray M., Duggan O. The adsorption of pollutants by peat, lignite and activated chars. Journal of Chemical Technology & Biotechnology 1997, 68:442-452.
14. Alloway B.J. Soil Processes and the Behaviour of Metals 1990, Son Inc., New York.
15. Amin M.N., Kaneco S., Kitagawa T., Begum A., Katsumata H., Suzuki T., Ohta K. Removal of arsenic in aqueous solutions by adsorption onto waste rice husk. Industrial & Engineering Chemistry Research 2006, 45:8105-8110.
16. Amonette J.E., Szecsody J.E., Schaef H.T., Templeton J.C., Gorby Y.A., Fruchter J.S. Abiotic Reduction of Aquifer Materials by Dithionite: A Promising in Situ Remediation Technology, Proceedings of the 33rd Hanford Symposium on Health and the Environment 1994, Battelle Press, Columbus, OH, Pasco, Washington.
17. Anderson A., Mitchell P. Treatment of Mercury-contaminated Soil, Mine Waste and Sludge Using Silica Micro-encapsulation, TMS Annual Meeting 2003, Extraction and Processing Division, San Diego, CA, pp. 265-274.
18. Anderson R.T., Vrionis H.A., Ortiz-Bernad I., Resch C.T., Long P.E., Dayvault R., Karp K., Marutzky S., Metzler D.R., Peacock A., White D.C., Lowe M., Lovley D.R. Stimulating the in situ activity of geobacter species to remove uranium from the groundwater of a uranium-contaminated aquifer. Applied and Environmental Microbiology 2003, 69:5884-5891.
19. Annachhatre A.P., Suktrakoolvait S. Biological sulfate reduction using molasses as a carbon source. Water Environment Research 2001, 73:118-126.
20. Apak R., Tutem E., Hugul M., Hizal J. Heavy metal cation retention by unconventional sorbents (red muds and fly ashes). Water Research 1998, 32:430-440.
21. Arwidsson Z., Elgh-Dalgren K., von Kronhelm T., Sjöberg R., Allard B., van Hees P. Remediation of heavy metal contaminated soil washing residues with amino polycarboxylic acids. Journal of Hazardous Materials 2010, 173:697-704.
22. AsçI Y., Nurbas M., Sag AçIkel Y. Investigation of sorption/desorption equilibria of heavy metal ions on/from quartz using rhamnolipid biosurfactant. Journal of Environmental Management 2010, 91:724-731.
23. Bañuelos G.S. Phyto-products may be essential for sustainability and implementation of phytoremediation. Environmental Pollution 2006, 144:19-23.
24. Baker A.J.M. Metal hyperaccumulation by plants: our present Knowledge of Ecophysiological phenomenon. Physiology and Molecular Biology 1995, Abstract Book: Fourteenth Annual Symposium in Current Topics in Plant Biochemistry, p. 7.
25. Bang S., Korfiatis G.P., Meng X. Removal of arsenic from water by zero-valent iron. Journal of Hazardous Materials 2005, 121:61-67.
26. Barbaro J.R., Barker J.F. Controlled field study on the use of nitrate and oxygen for bioremediation of a gasoline source zone. Bioremediation Journal 2000, 4:259-270.
27. Barona A., Aranguiz I., Elías A. Metal associations in soils before and after EDTA extractive decontamination: implications for the effectiveness of further clean-up procedures. Environmental Pollution 2001, 113:79-85.
28. Bartzas G., Komnitsas K. Solid phase studies and geochemical modelling of low-cost permeable reactive barriers. Journal of Hazardous Materials 2010, 183:301-308.
29. Bayramoglu G., Bektas S., ArIca M.Y. Biosorption of heavy metal ions on immobilized white-rot fungus Trametes versicolor. Journal of Hazardous Materials 2003, 101:285-300.
30. Benner S.G., Blowes D.W., Gould W.D., Herbert R.B., Ptacek C.J. Geochemistry of a permeable reactive barrier for metals and acid mine drainage. Environmental Science & Technology 1999, 33:2793-2799.
31. Bleeker P.M., Assunção A.G.L., Teiga P.M., de Koe T., Verkleij J.A.C. Revegetation of the acidic, as contaminated Jales mine spoil tips using a combination of spoil amendments and tolerant grasses. The Science of the Total Environment 2002, 300:1-13.
32. Blowes D.W., Ptacek C.J., Bain J.G., Waybrant K.R., Robertson W.D. Treatment of Mine Drainage Water Using in Situ Permeable Reactive Walls. Proceedings of Sudbury '95, Mining and the Environment 1995, 979-987. CANMET, Ottawa, ON 3.
33. Blowes D.W., Ptacek C.J., Benner S.G., Waybrant K.R., Bain J.G. Porous reactive walls for the prevention of acid mine drainage: a review. Mineral processing and extractive metallurgy review: An International Journal 1998, 19:25-37.
34. Blowes D.W., Ptacek C.J., Benner S.G., McRae C.W.T., Bennett T.A., Puls R.W. Treatment of inorganic contaminants using permeable reactive barriers. Journal of Contaminant Hydrology 2000, 45:123-137.
35. Blue L.Y., Van Aelstyn M.A., Matlock M., Atwood D.A. Low-level mercury removal from groundwater using a synthetic chelating ligand. Water Research 2008, 42:2025-2028.
36. Bodek I., Lyman W.J., Reehl W.F., Rosenblatt D.H. Environmental Inorganic Chemistry: Properties, Processes and Estimation Methods 1988, Pergamon Press, Elmsford, NY.
37. Boopathy R. Factors limiting bioremediation technologies. Bioresource Technology 2000, 74:63-67.
38. Bower J., Savage K.S., Weinman B., Barnett M.O., Hamilton W.P., Harper W.F. Immobilization of mercury by pyrite (FeS2). Environmental Pollution 2008, 156:504-514.
39. Braud A., Jézéquel K., Vieille E., Tritter A., Lebeau T. Changes in extractability of Cr and Pb in a Polycontaminated soil after bioaugmentation with microbial Producers of biosurfactants, organic acids and Siderophores. Water, Air, &; Soil Pollution: Focus 2006, 6:261-279.
40. Brown R.A., Leaby M.C., Pyrih R.Z. In situ remediation of metals comes of age. Remediation Journal 1998, 8:81-96.
41. Brunori C., Cremisini C., Massanisso P., Pinto V., Torricelli L. Reuse of a treated red mud bauxite waste: studies on environmental compatibility. Journal of Hazardous Materials 2005, 117:55-63.
42. Camacho L.M., Gutiérrez M., Alarcón-Herrera M.T., Villalba M.D.L., Deng S. Occurrence and treatment of arsenic in groundwater and soil in northern Mexico and southwestern USA. Chemosphere 2011, 83:211-225.
43. Cantrell K.J., Kaplan D.I. Zero-valent iron colloid emplacement in sand columns. Journal of Environmental Engineering 1997, 123:499-505.
44. Cantrell K.J., Kaplan D.I., Wietsma T.W. Zero-valent iron for the in situ remediation of selected metals in groundwater. Journal of Hazardous Materials 1995, 42:201-212.
45. Cardenas E., Wu W.-M., Leigh M.B., Carley J., Carroll S., Gentry T., Luo J., Watson D., Gu B., Ginder-Vogel M., Kitanidis P.K., Jardine P.M., Zhou J., Criddle C.S., Marsh T.L., Tiedje J.M. Microbial communities in contaminated sediments, associated with bioremediation of uranium to submicromolar levels. Applied and Environmental Microbiology 2008, 74:3718-3729.
46. Carlson L., Bigham J.M., Schwertmann U., Kyek A., Wagner F. Scavenging of As from acid mine drainage by Schwertmannite and Ferrihydrite: a comparison with synthetic analogues. Environmental Science & Technology 2002, 36:1712-1719.
47. Carriazo D., del Arco M., Martín C., Rives V. A comparative study between chloride and calcined carbonate hydrotalcites as adsorbents for Cr(VI). Applied Clay Science 2007, 37:231-239.
48. Cauwenberghe L.V. Electrokinetics: Technology Overview Report 1997, Groundwater Remediation Technologies Analysis Centre, pp. 1-17.
49. Chiarizia R., Horwitz E.P., Hodgon K.M. Removal of inorganic contaminants from groundwater. Environmental Remediation 1992, 509. ACS Symposium series. G.F. Vandergrift, D.T. Reed, I.R. Tasker (Eds.).
50. Chilingar G.V., Loo W.W., Khilyuk L.F., Katz S.A. Electrobioremediation of soils contaminated with hydrocarbons and metals: progress report. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 1997, 19:129-146.
51. Chowdhury S.R., Yanful E.K. Arsenic and chromium removal by mixed magnetite-maghemite nanoparticles and the effect of phosphate on removal. Journal of Environmental Management 2010, 91:2238-2247.
52. Chung H., Kim S.K., Lee Y.S., Yu J. Permeable reactive barrier using atomized slag material for treatment of contaminants from landfills. Geosciences Journal 2007, 11:137-145.
53. Chvedov D., Ostap S., Le T. Surface properties of red mud particles from potentiometric titration. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2001, 182:131-141.
54. Treatment of Chromium Contamination and Chromium Ore Processing Residue, Technical Bulletin (TB 14). Contaminated Land: Applications in Real Environment 2007, CL:AIRE, London, UK. http://www.claire.co.uk.
55. Clarke A.N., Oma K.H., Megehee M.M., Mutch R.D. Surfactant-Enhanced in Situ Remediation: Current and Future Techniques, 33rd Hanford Symposium on Health and the Environment 1994, Battelle Press, Columbus, OH, Pasco, Washington.
56. Colacicco A., De Gioannis G., Muntoni A., Pettinao E., Polettini A., Pomi R. Enhanced electrokinetic treatment of marine sediments contaminated by heavy metals and PAHs. Chemosphere 2010, 81:46-56.
57. Conca J.L., Wright J. An Apatite II permeable reactive barrier to remediate groundwater containing Zn, Pb and Cd. Applied Geochemistry 2006, 21:1288-1300.
58. Conca J.L., Lu N., Parker G., Moore B., Adams A., Wright J.V., Heller P. PIMS-Remediation of Metal Contaminated Waters and Soils 2000, Battelle Press, Columbus, Ohio.
59. Contin M., Mondini C., Leita L., Nobili M.D. Enhanced soil toxic metal fixation in iron (hydr)oxides by redox cycles. Geoderma 2007, 140:164-175.
60. Cornell R.M., Schwertmann U. The Iron Oxides: Structure, Properties, Reactions, Occurrences and Uses 2003, Wiley-VCH, Weinheim, Germany.
61. Cortina J.-L., Lagreca I., De Pablo J., Cama J., Ayora C. Passive in situ remediation of metal-polluted water with caustic magnesia: evidence from column experiments. Environmental Science & Technology 2003, 37:1971-1977.
62. Cuevas J., Ruiz A.I., de Soto I.S., Sevilla T., Procopio J.R., Da Silva P., Gismera M.J., Regadío M., Sánchez Jiménez N., Rodríguez Rastrero M., Leguey S. The performance of natural clay as a barrier to the diffusion of municipal solid waste landfill leachates. Journal of Environmental Management 2011, 10.1016/j.jenvman.2011.02.014.
63. Cundy A.B., Hopkinson L. Electrokinetic iron pan generation in unconsolidated sediments: implications for contaminated land remediation and soil engineering. Applied Geochemistry 2005, 20:841-848.
64. Cundy A.B., Hopkinson L., Whitby R.L.D. Use of iron-based technologies in contaminated land and groundwater remediation: a review. Science of the Total Environment 2008, 400:42-51.
65. Cunningham S., Berti W. Remediation of contaminated soils with green plants: an overview. In Vitro Cellular & Developmental Biology - Plant 1993, 29:207-212.
66. Czurda, K.A., 1998. Reactive walls with fly ash zeolites as surface active components, Proceedings, 11th Int. Clay Conference, Ottawa.
67. Czurda K.A., Haus R. Reactive barriers with fly ash zeolites for in situ groundwater remediation. Applied Clay Science 2002, 21:13-20.
68. Das D., Chatterjee A., Samanta G., Mandal B., Chowdhury T.R., Samanta G., Chowdhury P.P., Chanda C., Basu G., Lodh D., Nndi S., Chakraborty T., Mandal S., Bhattacharyua S.M., Chakraborti D. Report. Arsenic contamination in groundwater in six districts of West Bengal, India: the biggest arsenic calamity in the world. Analyst 1994, 119:168N-170N.
69. Demirbas E., Kobya M., Öncel S., Sencan S. Removal of Ni(II) from aqueous solution by adsorption onto hazelnut shell activated carbon: equilibrium studies. Bioresource Technology 2002, 84:291-293.
70. Dermatas D., Meng X. Utilization of fly ash for stabilization/solidification of heavy metal contaminated soils. Engineering Geology 2003, 70:377-394.
71. Dermont G., Bergeron M., Mercier G., Richer-Laflèche M. Soil washing for metal removal: a review of physical/chemical technologies and field applications. Journal of Hazardous Materials 2008, 152:1-31.
72. Di Palma L., Ferrantelli P., Merli C., Biancifiori F. Recovery of EDTA and metal precipitation from soil flushing solutions. Journal of Hazardous Materials 2003, 103:153-168.
73. Di Palma L., Ferrantelli P., Medici F. Heavy metals extraction from contaminated soil: recovery of the flushing solution. Journal of Environmental Management 2005, 77:205-211.
74. Diels, L., Geets, J., Dejonghe, W., Roy, S.V., Vanbroekhoven, K., Szewczyk, A., Malina, G., 2005. Heavy metal immobilization in groundwater by in situ bioprecipitation: comments and questions about carbon source use, efficiency and sustainability of the process, 9th International Mine Water Congress.
75. Dilek F.B., Erbay A., Yetis U. Ni(II) biosorption by Polyporous versicolor. Process Biochemistry 2002, 37:723-726.
76. DoD Environmental Technology Transfer Committee, 1994. Remediation Technologies Screening Matrix and Reference Guide, EPA/542/B-94/013, NTIS PB95-104782.
77. Doong R.A., Wu Y.W., Lei W.G. Surfactant enhanced remediation of cadmium contaminated soils. Water Science Technology 1998, 37:65-71.
78. Duruibe J.O., Ogwuegbu M.O.C., Egwurugwu J.N. Heavy metal pollution and human biotoxic effects. International Journal of Physical Sciences 2007, 2:112-118.
79. Dvorak D.H., Hedin R.S. Treatment of metal contaminated water using bacterial sulfate reduction: results from pilot-scale reactors. Biotechnology and Bioprocess Engineering 1992, 40:609-616.
80. Dwivedi C.P., Sahu J.N., Mohanty C.R., Mohan B.R., Meikap B.C. Column performance of granular activated carbon packed bed for Pb(II) removal. Journal of Hazardous Materials 2008, 156:596-603.
81. Dzombak D.A., Morel F.M.M. Surface Complexation Modeling, Hydrous Ferric Oxide 1990, Wiley-Interscience, New York, NY.
82. Evanko C.R., Dzombak D.A. Remediation of Metals-contaminated Soils and Groundwater, Technology Evaluation Report, TE-97-01 1997, Ground-Water Remediation Technologies Analysis Center, Pittsburg, PA.
83. Fan M., Marshall W., Daugaard D., Brown R.C. Steam activation of chars produced from oat hulls and corn stover. Bioresource Technology 2004, 93:103-107.
84. Fang Y., Hozalski R.M., Clapp L.W., Novak P.J., Semmens M.J. Passive dissolution of hydrogen gas into groundwater using hollow-fiber membranes. Water Research 2002, 36:3533-3542.
85. Faulkner D.W.S., Hopkinson L., Cundy A.B. Electrokinetic generation of reactive iron-rich barriers in wet sediments: implications for contaminated land management. Mineralogical Magazine 2005, 69:749-757.
86. Fine P., Scagnossi A., Chen Y., Mingelgrin U. Practical and mechanistic aspects of the removal of cadmium from aqueous systems using peat. Environmental Pollution 2005, 138:358-367.
87. Finneran K.T., Anderson R.T., Nevin K.P., Lovley D.R. Potential for bioremediation of uranium-contaminated aquifers with microbial U(VI) reduction. Soil and Sediment Contamination: An International Journal 2002, 11:339-357.
88. Finneran K.T., Housewright M.E., Lovley D.R. Multiple infl{ligature}uences of nitrate on uranium solubility during bioremediation of uranium-contaminated subsurface sediments. Environmental Microbiology 2002, 4:510-516.
89. Fletcher T. Neighborhood change at Love Canal: contamination, evacuation and resettlement. Land Use Policy 2002, 19:311-323.
90. Fruchter J.S., Cole C.R., Williams M.D., Vermeul V.R., Teel S.S., Amonette J.E., Szecsody J.E., Yabusaki S.B. Creation of a Subsurface Permeable Treatment Barrier Using in Situ Redox Manipulation 1997, Pacific Northwest National Laboratory, Richland, WA.
91. Fu F., Wang Q. Removal of heavy metal ions from wastewaters: a review. Journal of Environmental Management 2011, 92:407-418.
92. Fuller C.C., Piana M.J., Bargar J.R., Davis J.A., Kohler M. Evaluation of apatite materials for use in permeable reactive barriers for the remediation of uranium-contaminated groundwater. Handbook of Groundwater Remediation Using Permeable Reactive Barriers 2003, 255-280. Academic Press, San Diego. L.N. David, J.M. Stan, C.F. Christopher, A.D. James (Eds.).
93. Gaballah I., Kilbertus G. Recovery of heavy metal ions through decontamination of synthetic solutions and industrial effluents using modified barks. Journal of Geochemical Exploration 1998, 62:241-286.
94. Garbarino J.R., Hayes H., Roth D., Antweider R., Brinton T.I., Taylor H. Contaminants in the Mississippi river 1995, U. S. Geological Survey Circular, Virginia, U.S.A, 1133.
95. Gavaskar A.R. Design and construction techniques for permeable reactive barriers. Journal of Hazardous Materials 1999, 68:41-71.
96. Gavaskar A.R., Gupta N., Sass B.M., Janosy R.J., O'Sullivan D. Permeable Barriers for Groundwater Remediation: Design, Construction and Monitoring 1998, Battelle Press, Columbus, Ohio.
97. Geckeler K.E., Volchek K. Removal of hazardous substances from water using ultrafiltration in conjunction with soluble polymers. Environmental Science & Technology 1996, 30:725-734.
98. Geets J., Diels L., Geert K.V., Brummeler E.T., Broek P.v.d., Ghyoot W., Feyaerts K., Gevaerts W. Proceedings Consoil 2003 2003, pp. 1641-1648.
99. Giannis A., Gidarakos E. Washing enhanced electrokinetic remediation for removal cadmium from real contaminated soil. Journal of Hazardous Materials 2005, 123:165-175.
100. Giannis A., Gidarakos E., Skouta A. Application of sodium dodecyl sulfate and humic acid as surfactants on electrokinetic remediation of cadmium-contaminated soil. Desalination 2007, 211:249-260.
101. Gibert O., de Pablo J., Cortina J.L., Ayora C. Treatment of acid mine drainage by sulphate-reducing bacteria using permeable reactive barriers: a review from laboratory to full-scale experiments. Reviews in Environmental Science and Biotechnology 2002, 1:327-333.
102. Gibson G.R. Physiology and ecology of the sulphate-reducing bacteria. Journal of Applied Microbiology 1990, 69:769-797.
103. Gillham R.W., OíHannesin S.F., Orth W.S. Metal enhanced abiotic degradation of halogenated aliphatics: laboratory tests and field trials. Proceedings of the 6th Annual Environmental Management and Technical Conference/Haz. Mat. Central Conference. Advanstar Exposition, Glen Ellyn, IL, Rosemont, Illinois 1993, 440-461.
104. Greben H.A., Maree J.P., Singmin Y., Mnqanqeni S. Biological sulphate removal from acid mine effluent using ethanol as carbon and energy source. Water Science and Technology 2000, 42:339-344.
105. Groudev S., Spasova I., Nicolova M., Georgiev P. In situ bioremediation of contaminated soils in uranium deposits. Hydrometallurgy 2010, 104:518-523.
106. Gu Z., Deng B. Use of iron-containing mesoporous carbon (IMC) for arsenic removal from drinking water. Environmental Engineering Science 2006, 24:113-121.
107. Gu B., Phelps T.J., Liang L., Dickey M.J., Roh Y., Kinsall B.L., Palumbo A.V., Jacobs G.K. Biogeochemical dynamics in zero-valent iron columns: implications for permeable reactive barriers. Environmental Science & Technology 1999, 33:2170-2177.
108. Gu Z., Fang J., Deng B. Preparation and evaluation of GAC-Based iron-containing adsorbents for arsenic removal. Environmental Science & Technology 2005, 39:3833-3843.
109. Gupta V.K., Suhas, Ali I., Saini V.K. Removal of Rhodamine B, fast green, and Methylene Blue from wastewater using red mud, an aluminum industry waste. Industrial & Engineering Chemistry Research 2004, 43:1740-1747.
110. Gupta V.K., Sharma S. Removal of cadmium and zinc from aqueous solutions using red mud. Environmental Science & Technology 2002, 36:3612-3617.
111. Gupta V.K., Ali I., Saini V.K. Removal of Chlorophenols from wastewater using red Mud: an aluminum industry waste. Environmental Science & Technology 2004, 38:4012-4018.
112. Hammack R.W., Edenborn H.M. The removal of nickel from mine waters using bacterial sulfate reduction. Applied Microbiology and Biotechnology 1992, 37:674-678.
113. Hammack R.W., Edenborn H.M., Dvorak D.H. Treatment of water from an open-pit copper mine using biogenic sulfide and limestone: a feasibility study. Water Research 1994, 28:2321-2329.
114. Hammer M.J., Hammer M.J.J. Water Quality, Water and Waste Water Technology 2004, Prentice-Hall, New Jersey, pp. 139-159. fifth ed.
115. Han I., Schlautman M.A., Batchelor B. Removal of hexavalent chromium from groundwater by granular activated carbon. Water Environmental Research 2000, 72:29-39.
116. Han D., Halada Gary P., Spalding B., Brooks Scott C. Electrospun and Oxidized Cellulosic Materials for Environmental Remediation of Heavy Metals in Groundwater, Model Cellulosic Surfaces 2009, American Chemical Society, 243-257.
117. Hansen H.K., Ottosen L.M., Laursen S., Villumsen A. Electrochemical analysis of ion-exchange membranes with respect to a possible use in electrodialytic decontamination of soil polluted with heavy metals. Separation Science and Technology 1997, 32:2425-2444.
118. Hartley W., Lepp N.W. Remediation of arsenic contaminated soils by iron-oxide application, evaluated in terms of plant productivity, arsenic and phytotoxic metal uptake. Science of the Total Environment 2008, 390:35-44.
119. Hartley W., Edwards R., Lepp N.W. Arsenic and heavy metal mobility in iron oxide-amended contaminated soils as evaluated by short- and long-term leaching tests. Environmental Pollution 2004, 131:495-504.
120. Hasan S., Hashim M.A., Gupta B.S. Adsorption of Ni(SO4) on Malaysian rubber-wood ash. Bioresource Technology 2000, 72:153-158.
121. Hasan S., Ghosh T.K., Viswanath D.S., Loyalka S.K., Sengupta B. Preparation and evaluation of fullers earth beads for removal of cesium from waste streams. Separation Science and Technology 2007, 42:717-738.
122. Hazardous Waste Consultants, 1995. pp. 1.3-1.4.
123. Heal K., Younger P.L., Smith K., Glendinning S., Quinn P., Dobbie K. Novel use of ochre from mine water treatment plants to reduce point and diffuse phosphorus pollution. Land Contamination and Reclamation 2003, 11:145-152.
124. Hellerich L.A., Nikolaidis N.P., Dobbs G.M. Evaluation of the potential for the natural attenuation of hexavalent chromium within a sub-wetland ground water. Journal of Environmental Management 2008, 88:1513-1524.
125. Hockin S.L., Gadd G.M. Linked redox precipitation of sulfur and selenium under anaerobic conditions by sulfate-reducing bacterial Biofilms. Applied and Environmental Microbiology 2003, 69:7063-7072.
126. Holleman A.F., Wiberg E., Wiberg N. Iron 1985, in German, Lehrbuch der Anorganischen Chemie.
127. Hong S., Zhang H., Duttweiler C.M., Lemley A.T. Degradation of methyl tertiary-butyl ether (MTBE) by anodic Fenton treatment. Journal of Hazardous Materials 2007, 144:29-40.
128. Hong P.K.A., Cai X., Cha Z. Pressure-assisted chelation extraction of lead from contaminated soil. Environmental Pollution 2008, 153:14-21.
129. Hopkinson L., Cundy A.B. FIRS (Ferric Iron Remediation and Stabilization): A Novel Electrokinetic Technique for Soil Remediation and Engineering. CL: AIRE Res Bull 2003, Available from:. http://www.claire.co.uk/.
130. Hsieh L.-H.C., Weng Y.-H., Huang C.-P., Li K.-C. Removal of arsenic from groundwater by electro-ultrafiltration. Desalination 2008, 234:402-408.
131. Hu J., Chen G., Lo I.M.C. Removal and recovery of Cr(VI) from wastewater by maghemite nanoparticles. Water Research 2005, 39:4528-4536.
132. Hunkeler D., Höhener P., Zeyer J. Engineered and subsequent intrinsic in situ bioremediation of a diesel fuel contaminated aquifer. Journal of Contaminant Hydrology 2002, 59:231-245.
133. Hunter W., Kuykendall L. Removing selenite from groundwater with an in situ biobarrier: laboratory studies. Current Microbiology 2005, 50:145-150.
134. Huttenloch P., Roehl K.E., Czurda K. Sorption of nonpolar aromatic contaminants by chlorosilane surface modified natural minerals. Environmental Science & Technology 2001, 35:4260-4264.
135. Permeable Reactive Barriers: Lessons Learned/New Directions. PRB-4 2005, ITRC, Interstate Technology & Regulatory Council, Permeable Reactive Barriers Team, Washington, D.C., pp. 28-29.
136. Isoyama M., Wada S.I. Remediation of Pb-contaminated soils by washing with hydrochloric acid and subsequent immobilization with calcite and allophanic soil. Journal of Hazardous Materials 2007, 143:636-642.
137. Istok J.D., Senko J.M., Krumholz L.R., Watson D., Bogle M.A., Peacock A., Chang Y.J., White D.C. In situ bioreduction of technetium and uranium in a nitrate-contaminated aquifer. Environmental Science & Technology 2003, 38:468-475.
138. Material Safety Data Sheet for JBR425 2001, JENEIL Biosurfactant Co. LLC. http://www.biosurfactant.com/downloads/jbr425msds.pdf.
139. James S.V., Stacy G.L. Overview of Separation Technologies for EPA's Superfund Innovative Technology Evaluation Program 1993, Gulf Publishing, Houston, TX.
140. Janssen G.M.C.M., Temminghoff E.J.M. In situ metal precipitation in a zinc-contaminated, aerobic sandy aquifer by means of biological sulfate reduction. Environmental Science & Technology 2004, 38:4002-4011.
141. Jarvis A.P., Moustafa M., Orme P.H.A., Younger P.L. Effective remediation of grossly polluted acidic, and metal-rich, spoil heap drainage using a novel, low-cost, permeable reactive barrier in Northumberland, UK. Environmental Pollution 2006, 143:261-268.
142. Jeen S.-W., Gillham R.W., Przepiora A. Predictions of long-term performance of granular iron permeable reactive barriers: field-scale evaluation. Journal of Contaminant Hydrology 2011, 123:50-64.
143. Jeyasingh J., Somasundaram V., Philip L., Bhallamudi S.M. Pilot scale studies on the remediation of chromium contaminated aquifer using bio-barrier and reactive zone technologies. Chemical Engineering Journal 2011, 167:206-214.
144. Joo S.H., Feitz A.J., Waite T.D. Oxidative degradation of the carbothioate herbicide, molinate, using nanoscale zero-valent iron. Environmental Science & Technology 2004, 38:2242-2247.
145. Jun D., Yongsheng Z., Weihong Z., Mei H. Laboratory study on sequenced permeable reactive barrier remediation for landfill leachate-contaminated groundwater. Journal of Hazardous Materials 2009, 161:224-230.
146. Kalin R.M. Engineered passive bioreactive barriers: risk-managing the legacy of industrial soil and groundwater pollution. Current Opinion in Microbiology 2004, 7:227-238.
147. Kameda T., Saito S., Umetsu Y. Mg-Al layered double hydroxide intercalated with ethylene-diaminetetraacetate anion: synthesis and application to the uptake of heavy metal ions from an aqueous solution. Separation and Purification Technology 2005, 47:20-26.
148. Kamel S., Hassan E.M., El-Sakhawy M. Preparation and application of acrylonitrile-grafted cyanoethyl cellulose for the removal of copper (II) ions. Journal of Applied Polymer Science 2006, 100:329-334.
149. Kanel S.R., Choi H., Kim J.-Y., Vigneswaran S., Shim W.G. Removal of arsenic(III) from groundwater using low-cost industrial by-products-blast furnace slag. The Water Quality Research Journal of Canada 2006, 41:130-139.
150. Katsoyiannis I.A., Zouboulis A.I. Application of biological processes for the removal of arsenic from groundwaters. Water Research 2004, 38:17-26.
151. Kavamura V.N., Esposito E. Biotechnological strategies applied to the decontamination of soils polluted with heavy metals. Biotechnology Advances 2010, 28:61-69.
152. Khan F.I., Husain T., Hejazi R. An overview and analysis of site remediation technologies. Journal of Environmental Management 2004, 71:95-122.
153. Kim K.-R., Owens G. Potential for enhanced phytoremediation of landfills using biosolids - a review. Journal of Environmental Management 2010, 91:791-797.
154. Kim J.S., Shea P.J., Yang J.E., Kim J.-E. Halide salts accelerate degradation of high explosives by zerovalent iron. Environmental Pollution 2007, 147:634-641.
155. Kim M., Um H.-J., Bang S., Lee S.-H., Oh S.-J., Han J.-H., Kim K.-W., Min J., Kim Y.-H. Arsenic removal from Vietnamese groundwater using the arsenic-binding DNA Aptamer. Environmental Science & Technology 2009, 43:9335-9340.
156. Kocaoba S. Adsorption of Cd(II), Cr(III) and Mn(II) on natural sepiolite. Desalination 2009, 244:24-30.
157. Kocaoba S., Orhan Y., Akyüz T. Kinetics and equilibrium studies of heavy metal ions removalby use of natural zeolite. Desalination 2007, 214:1-10.
158. Komnitsas K., Bartzas G., Paspaliaris I. Efficiency of limestone and red mud barriers: laboratory column studies. Minerals Engineering 2004, 17:183-194.
159. Komnitsas K., Bartzas G., Fytas K., Paspaliaris I. Long-term efficiency and kinetic evaluation of ZVI barriers during clean-up of copper containing solutions. Minerals Engineering 2007, 20:1200-1209.
160. Korngold E., Belfer S., Urtizberea C. Removal of heavy metals from tap water by a cation exchanger. Desalination 1996, 104:197-201.
161. Kos B., Lestan D. Chelator induced phytoextraction and in situ soil washing of Cu. Environmental Pollution 2004, 132:333-339.
162. Kovanda F., Kovácsová E., Koloušek D. Removal of anions from solution by calcined hydrotalcite and regeneration of used sorbent in repeated calcination-rehydration-anion exchange processes. Collection of Czechoslovak Chemical Communications 1999, 64:1517-1528.
163. Kumpiene J., Ore S., Renella G., Mench M., Lagerkvist A., Maurice C. Assessment of zerovalent iron for stabilization of chromium, copper, and arsenic in soil. Environmental Pollution 2006, 144:62-69.
164. LaGrega M.D., Buckingham P.L., Evans J.C. Hazardous Waste Management 1994, McGraw Hill, New York.
165. Langley S., Gault A.G., Ibrahim A., Takahashi Y., Renaud R., Fortin D., Clark I.D., Ferris F.G. Sorption of strontium onto bacteriogenic iron oxides. Environmental Science & Technology 2009, 43:1008-1014.
166. Lazaridis N.K. Sorption removal of anions and cations in single batch systems by uncalcined and calcined mg-Al-CO3 hydrotalcite. Water, Air, & Soil Pollution 2003, 146:127-139.
167. Lee K.-Y., Kim K.-W. Heavy metal removal from shooting range soil by hybrid electrokinetics with bacteria and enhancing agents. Environmental Science & Technology 2010, 44:9482-9487.
168. Lee J., Graettinger A.J., Moylan J., Reeves H.W. Directed site exploration for permeable reactive barrier design. Journal of Hazardous Materials 2009, 162:222-229.
169. Leglize, P., 2004. Bacteria-phenanthrene-activated Carbon Interactions Studies for PRB Process Evaluation, Dissertation Faculty of Sciences and Technology of Nancy. ADEME, Research Programme Planning, Cedex, France, France.
170. Leist M., Casey R.J., Caridi D. The fixation and leaching of cement stabilized arsenic. Waste Management 2003, 23:353-359.
171. Lenntech Water Treatment 2004, Lenntech, Rotterdamseweg, Netherlands, (Lenntech Water Treatment and Air Purification).
172. Lens P.N.L., Omil F., Lema J.M., Pol L.W.H. Environmental technologies to treat sulfur pollution. Principles and Engineering 2000, 153-173. IWA Publishing, London. P.N.L. Lens, L.W.H. Pol (Eds.).
173. Lestan D., Luo C.-l., Li X.-d. The use of chelating agents in the remediation of metal-contaminated soils: a review. Environmental Pollution 2008, 153:3-13.
174. Leung H.M., Ye Z.H., Wong M.H. Interactions of mycorrhizal fungi with Pteris vittata (As hyperaccumulator) in As-contaminated soils. Environmental Pollution 2006, 139:1-8.
175. Leupin O.X., Hug S.J. Oxidation and removal of arsenic (III) from aerated groundwater by filtration through sand and zero-valent iron. Water Research 2005, 39:1729-1740.
176. Li L., Benson C.H., Lawson E.M. Impact of mineral fouling on hydraulic behavior of permeable reactive barriers. Ground Water 2005, 43:582-596.
177. Li L., Benson C.H., Lawson E.M. Modeling porosity reductions caused by mineral fouling in continuous-wall permeable reactive barriers. Journal of Contaminant Hydrology 2006, 83:89-121.
178. Li M.S., Luo Y.P., Su Z.Y. Heavy metal concentrations in soils and plant accumulation in a restored manganese mineland in Guangxi, South China. Environmental Pollution 2007, 147:168-175.
179. Li Y., Wang J., Luan Z., Liang Z. Arsenic removal from aqueous solution using ferrous based red mud sludge. Journal of Hazardous Materials 2010, 177:131-137.
180. Liang L., Moline G.R., Kamolpornwijit W., West O.R. Influence of hydrogeochemical processes on zero-valent iron reactive barrier performance: a field investigation. Journal of Contaminant Hydrology 2005, 78:291-312.
181. Lim T.-T., Tay J.-H., Wang J.-Y. Chelating-agent-enhanced heavy metal extraction from a contaminated acidic soil. Journal of Environmental Engineering 2004, 130:59-66.
182. Liu J.-f., Zhao Z.-s., Jiang G.-b. Coating Fe3O4 magnetic nanoparticles with humic acid for high efficient removal of heavy metals in water. Environmental Science & Technology 2008, 42:6949-6954.
183. Lombi E., Zhao F.-J., Zhang G., Sun B., Fitz W., Zhang H., McGrath S.P. In situ fixation of metals in soils using bauxite residue: chemical assessment. Environmental Pollution 2002, 118:435-443.
184. Lorenzen L., van Deventer J.S.J., Landi W.M. Factors affecting the mechanism of the adsorption of arsenic species on activated carbon. Minerals Engineering 1995, 8:557-569.
185. Lovley D.R., Phillips E.J.P., Gorby Y.A., Landa E.R. Microbial reduction of uranium. Nature 1991, 350:413-416.
186. Ludwig R.D., Su C., Lee T.R., Wilkin R.T., Acree S.D., Ross R.R., Keeley A. In situ chemical reduction of Cr(VI) in groundwater using a combination of ferrous sulfate and sodium dithionite: a field investigation. Environmental Science & Technology 2007, 41:5299-5305.
187. Ludwig R.D., Smyth D.J.A., Blowes D.W., Spink L.E., Wilkin R.T., Jewett D.G., Weisener C.J. Treatment of arsenic, heavy metals, and acidity using a mixed ZVI-Compost PRB. Environmental Science & Technology 2009, 43:1970-1976.
188. Luo C., Shen Z., Lou L., Li X. EDDS and EDTA-enhanced phytoextraction of metals from artificially contaminated soil and residual effects of chelant compounds. Environmental Pollution 2006, 144:862-871.
189. Mackenzie K., Schierz A., Georgi A., Kopinke F.-D. Colloidal activated carbon and carbo-iron - novel materials. Global NEST Journal 2008, 10:54-61.
190. Manning B.A., Hunt M.L., Amrhein C., Yarmoff J.A. Arsenic(III) and arsenic(V) reactions with zerovalent iron corrosion products. Environmental Science & Technology 2002, 36:5455-5461.
191. Marchiol L., Assolari S., Sacco P., Zerbi G. Phytoextraction of heavy metals by canola (Brassica napus) and radish (Raphanus sativus) grown on multicontaminated soil. Environmental Pollution 2004, 132:21-27.
192. Martínez M., Miralles N., Hidalgo S., Fiol N., Villaescusa I., Poch J. Removal of lead(II) and cadmium(II) from aqueous solutions using grape stalk waste. Journal of Hazardous Materials 2006, 133:203-211.
193. Matthews P.J., Davis R.D. Control of metal application rates from sewage sludge utilization in agriculture. Critical Reviews in Environmental Control 1984, 14:199-250.
194. McPhillips, Loren, C., 1991. Case History: Effective Groundwater Remediation at the United Chrome Superfund Site, Prepared for presentation at the 84th Annual Meeting and Exhibition of the Air and Waste Management Association, Vancouver, British Columbia.
195. Means J.L., Hinchee R.E. Emerging Technology for Bioremediation of Metals 1994, Lewis Publishers, Boca Raton, FL.
196. Means J.L., Kucak T., Crerar D.A. Relative degradation rates of NTA, EDTA and DTPA and environmental implications. Environmental Pollution Series B, Chemical and Physical 1980, 1:45-60.
197. Medscape, "Toxicity, Iron", Retrieved 2010-09-06. http://www.emedicine.com/emerg/topic285.htm.
198. Mench M., Bussiere S., Boisson J., Castaing E., Vangronsveld J., Ruttents A., Koe T.D., Bleeker P., Assuncao A., Manceau A. Progress in remediation and revegetation of the barren Jales gold mine spoil after in situ treatment. Plant and Soil 2003, 249:187-202.
199. Mench M., Vangronsveld J., Beckx C., Ruttens A. Progress in assisted natural remediation of an arsenic contaminated agricultural soil. Environmental Pollution 2006, 144:51-61.
200. Meng X., Korfiatis G.P. Removal of arsenic from Bangladesh well water using a household filtration system. BUET-UNU International Workshop on Technologies for Arsenic Removal from Drinking Water, Dhaka, Bangladesh 2001, M.F. Ahmed, M.A. Ali, Z. Adeel (Eds.).
201. Michalsen M.M., Peacock A.D., Smithgal A.N., White D.C., Spain A.M., Sanchez-Rosario Y., Krumholz L.R., Kelly S.D., Kemner K.M., McKinley J., Heald S.M., Bogle M.A., Watson D.B., Istok J.D. Treatment of nitric acid-, U(VI)-, and Tc(VII)-contaminated groundwater in intermediate-scale physical models of an in situ biobarrier. Environmental Science & Technology 2009, 43:1952-1961.
202. Mills T., Arnold B., Sivakumaran S., Northcott G., Vogeler I., Robinson B., Norling C., Leonil D. Phytoremediation and long-term site management of soil contaminated with pentachlorophenol (PCP) and heavy metals. Journal of Environmental Management 2006, 79:232-241.
203. Mohan D., Chander S. Removal and recovery of metal ions from acid mine drainage using lignite-a low cost sorbent. Journal of Hazardous Materials 2006, 137:1545-1553.
204. Mohan D., Pittman J.C.U. Arsenic removal from water/wastewater using adsorbents-a critical review. Journal of Hazardous Materials 2007, 142:1-53.
205. Mohan D., Pittman J.C.U., Bricka M., Smith F., Yancey B., Mohammad J., Steele P.H., Alexandre-Franco M.F., Serrano V.G., Gong H. Sorption of arsenic, cadmium, and lead by chars produced from fast pyrolysis of wood and bark during bio-oil production. Journal of Colloid and Interface Science 2007, 310.
206. Mon J., Deng Y., Flury M., Harsh J.B. Cesium incorporation and diffusion in cancrinite, sodalite, zeolite, and allophane. Microporous and Mesoporous Materials 2005, 86:277-286.
207. Moon D.H., Wazne M., Yoon I.-H., Grubb D.G. Assessment of cement kiln dust (CKD) for stabilization/solidification (S/S) of arsenic contaminated soils. Journal of Hazardous Materials 2008, 159:512-518.
208. Moore R.E., Mark R., Matsumoto Investigation of the Use of In-Situ Soil Flushing to Remediate a Lead Contaminated Site, Hazardous and Industrial Waste. Proceedings, Mid-Atlantic Industrial Waste Conference 1993, Technical Publishing Company, Inc., Lancaster, Pennsylvania.
209. Moraci N., Calabrò P.S. Heavy metals removal and hydraulic performance in zero-valent iron/pumice permeable reactive barriers. Journal of Environmental Management 2010, 91:2336-2341.
210. Moreno-Jiménez E., Vázquez S., Carpena-Ruiz R.O., Esteban E., Peñalosa J.M. Using Mediterranean shrubs for the phytoremediation of a soil impacted by pyritic wastes in Southern Spain: a field experiment. Journal of Environmental Management 2011, 92:1584-1590.
211. Morrison S.J., Metzler D.R., Dwyer B.P. Removal of As, Mn, Mo, Se, U, V and Zn from groundwater by zero-valent iron in a passive treatment cell: reaction progress modeling. Journal of Contaminant Hydrology 2002, 56:99-116.
212. Mouser P.J., N'Guessan A.L., Elifantz H., Holmes D.E., Williams K.H., Wilkins M.J., Long P.E., Lovley D.R. Influence of Heterogeneous ammonium availability on bacterial community structure and the expression of nitrogen fixation and ammonium transporter genes during in situ bioremediation of uranium-contaminated groundwater. Environmental Science & Technology 2009, 43:4386-4392.
213. Mulligan C.N., Wang S. Remediation of a heavy metal-contaminated soil by a rhamnolipid foam. Engineering Geology 2006, 85:75-81.
214. Mulligan C.N., Yong R.N. Natural attenuation of contaminated soils. Environment International 2004, 30:587-601.
215. Mulligan C.N., Yong R.N., Gibbs B.F. On the use of biosurfactants for the removal of heavy metals from oil-contaminated soil. Environmental Progress 1999, 18:50-54.
216. Mulligan C.N., Yong R.N., Gibbs B.F. Removal of heavy metals from contaminated soil and sediments using the biosurfactant surfactin. Journal of Soil Contamination 1999, 8:231-254.
217. Mulligan C.N., Yong R.N., Gibbs B.F. Remediation technologies for metal-contaminated soils and groundwater: an evaluation. Engineering Geology 2001, 60:193-207.
218. Munagapati V.S., Yarramuthi V., Nadavala S.K., Alla S.R., Abburi K. Biosorption of Cu(II), Cd(II) and Pb(II) by Acacia leucocephala bark powder: kinetics, equilibrium and thermodynamics. Chemical Engineering Journal 2010, 157:357-365.
219. Nadaroglu H., Kalkan E., Demir N. Removal of copper from aqueous solution using red mud. Desalination 2010, 251:90-95.
220. Nasiri F., Huang G., Fuller N. Prioritizing groundwater remediation policies: a fuzzy compatibility analysis decision aid. Journal of Environmental Management 2007, 82:13-23.
221. Nathanail C.P., Bardos R.P. Reclamation of Contaminated Land 2004, Wiley, Chicester.
222. Navarro P., Alguacil F.J. Adsorption of antimony and arsenic from a copper electrorefining solution onto activated carbon. Hydrometallurgy 2002, 66:101-105.
223. Navarro A., Martínez F. The use of soil-flushing to remediate metal contamination in a smelting slag dumping area: column and pilot-scale experiments. Engineering Geology 2010, 115:16-27.
224. Naveau A., Monteil-Rivera F., Guillon E., Dumonceau J. Interactions of aqueous selenium (-II) and (IV) with metallic sulfide surfaces. Environmental Science & Technology 2007, 41:5376-5382.
225. Norihiro M., Mitsuaki T., Ryo S., Hideki Y., Junji S. Removal of toxic heavy metal ions in aqueous solution with Mg/Al type hydrotalcite derived from wastes. Kagaku Kogaku Ronbunshu 2005, 31:285-290.
226. North N.N., Dollhopf S.L., Petrie L., Istok J.D., Balkwill D.L., Kostka J.E. Change in bacterial community structure during in situ biostimulation of subsurface sediment cocontaminated with uranium and nitrate. Applied and Environmental Microbiology 2004, 70:4911-4920.
227. O'Connell D.W., Birkinshaw C., O'Dwyer T.F. Heavy metal adsorbents prepared from the modification of cellulose: a review. Bioresource Technology 2008, 99:6709-6724.
228. Oh B.-T., Alvarez P. Hexahydro-1,3,5-Trinitro-1,3,5-Triazine (Rdx) degradation in biologically-active iron columns. Water, Air, &; Soil Pollution 2002, 141:325-335.
229. Pérez M.R., Pavlovic I., Barriga C., Cornejo J., Hermosín M.C., Ulibarri M.A. Uptake of Cu2+, Cd2+ and Pb2+ on Zn-al layered double hydroxide intercalated with EDTA. Applied Clay Science 2006, 32:245-251.
230. Pamukcu S., Wittle J.K. Electrokinetic removal of selected heavy metals from soil. Environmental Progress 1992, 11:241-250.
231. Pandey P.K., Verma Y., Choubey S., Pandey M., Chandrasekhar K. Biosorptive removal of cadmium from contaminated groundwater and industrial effluents. Bioresource Technology 2008, 99:4420-4427.
232. Park J.-B., Lee S.-H., Lee J.-W., Lee C.-Y. Lab scale experiments for permeable reactive barriers against contaminated groundwater with ammonium and heavy metals using clinoptilolite (01-29B). Journal of Hazardous Materials 2002, 95:65-79.
233. Park H., Kanel Sushil R., Choi H. Arsenic Removal by Nano-scale Zero Valent Iron and How It Is Affected by Natural Organic Matter, Environmental Applications of Nanoscale and Microscale Reactive Metal Particles 2009, American Chemical Society, 135-161.
234. Parkin, G.F., Alvarez, P.J., Scherer, M.M., Schnoor, J.L., 2000. Role of Microbes in Remediation with Fe(0) Reactive Barriers. Ground Water Currents USEPA 542-N-00-002, 2.
235. Periasamy K., Namasivayam C. Removal of copper(II) by adsorption onto peanut hull carbon from water and copper plating industry wastewater. Chemosphere 1996, 32:769-789.
236. Peternele W.S., Winkler-Hechenleitner A.A., Gómez Pineda E.A. Adsorption of Cd(II) and Pb(II) onto functionalized formic lignin from sugar cane bagasse. Bioresource Technology 1999, 68:95-100.
237. Peters R.W. Chelant extraction of heavy metals from contaminated soils. Journal of Hazardous Materials 1999, 66:151-210.
238. Pociecha M., Lestan D. Electrochemical EDTA recycling with sacrificial Al anode for remediation of Pb contaminated soil. Environmental Pollution 2010, 158:2710-2715.
239. Ponder S.M., Darab J.G., Mallouk T.E. Remediation of Cr(VI) and Pb(II) aqueous solutions using supported, nanoscale zero-valent iron. Environmental Science & Technology 2000, 34:2564-2569.
240. Prakasham R.S., Merrie J.S., Sheela R., Saswathi N., Ramakrishna S.V. Biosorption of chromium VI by free and immobilized Rhizopus arrhizus. Environmental Pollution 1999, 104:421-427.
241. Prasad D., Wai M., Berube P., Henry J.G. Evaluating substrates in the biological treatment of acid mine drainage. Environmental Technology 1999, 20:449-458.
242. Puls R.W., Paul C.J., Powell R.M. The application of in situ permeable reactive (zero-valent iron) barrier technology for the remediation of chromate-contaminated groundwater: a field test. Applied Geochemistry 1999, 14:989-1000.
243. Römkens P., Bouwman L., Japenga J., Draaisma C. Potentials and drawbacks of chelate-enhanced phytoremediation of soils. Environmental Pollution 2002, 116:109-121.
244. Rötting T.S., Cama J., Ayora C., Cortina J.-L., De Pablo J. Use of caustic magnesia to remove cadmium, nickel, and cobalt from water in passive treatment Systems: column experiments. Environmental Science & Technology 2006, 40:6438-6443.
245. Rahman M.H., Wasiuddin N.M., Islam M.R. Experimental and numerical modeling studies of arsenic removal with wood ash from aqueous streams. The Canadian Journal of Chemical Engineering 2004, 82:968-977.
246. Rajaković L.V. The sorption of arsenic onto activated carbon impregnated with metallic silver and copper. Separation Science and Technology 1992, 27:1423-1433.
247. Rangsayatorn N., Upatham E.S., Kruatrachue M., Pokethitiyook P., Lanza G.R. Phytoremediation potential of Spirulina (Arthrospira) platensis: biosorption and toxicity studies of cadmium. Environmental Pollution 2002, 119:45-53.
248. Rao T.S., Karthikeyan J. Removal of As(V) from Water by Adsorption on to Low-cost and Waste Materials. Progress in Environmental Science and Technology 2007, Science Press, Beijing, China, 684-691.
249. Raymond, R.L., 1974. Reclamation of Hydrocarbon Contaminated Ground Waters, US Patent Office. 3846290.
250. Reddad Z., Gérente C., Andrès Y., Thibault J.-F., Le Cloirec P. admium and lead adsorption by a natural polysaccharide in MF membrane reactor: experimental analysis and modelling. Water Research 2003, 37:3983-3991.
251. Reddy K.R., Parupudi U.S. Removal of chromium, nickel and cadmium from clays by in-situ electrokinetic remediation. Journal of Soil Contamination 1997, 6:391-407.
252. Reddy K.J., Blaylock M.J., Vance G.F., See R.B. Effects of redox potential on the speciation of selenium in ground water and coal-mine backfill materials, Wyoming. Proceedings of the 12th Annual National Meeting of the American Society for Surface Mining and Reclamation. WV 1995, 230-236. American Society for Surface Mining and Reclamation, Princeton. G.E. Schuman, G.F. Vance (Eds.).
253. Regelink I.C., Temminghoff E.J.M. Ni adsorption and Ni-Al LDH precipitation in a sandy aquifer: an experimental and mechanistic modeling study. Environmental Pollution 2011, 159:716-721.
254. Regvar M., Vogel-Mikus K., Kugonic N., Turk B., Batic F. Vegetational and mycorrhizal successions at a metal polluted site: indications for the direction of phytostabilisation?. Environmental Pollution 2006, 144:976-984.
255. Ricordel S., Taha S., Cisse I., Dorange G. Heavy metals removal by adsorption onto peanut husks carbon: characterization, kinetic study and modeling. Separation and Purification Technology 2001, 24:389-401.
256. Robertson W.D., Cherry J.A. In situ denitrification of septic-system nitrate using reactive porous media barriers: field trials. Ground Water 1995, 33:99-111.
257. Roehl K.E., Meggyes T., Simon F.G., Stewart D.I. Long-term Performance of Permeable Reactive Barriers 2005, Elsevier Publishers.
258. Ron E.Z., Rosenberg E. Natural roles of biosurfactants. Environmental Microbiology 2001, 3:229-236.
259. Rosetti, P.K., 1993. Possible Methods of Washing Fine Soil Particles Contaminated with Heavy Metals and Radionuclides, M.S. Thesis. Carnegie Mellon University, Pittsburgh, PA.
260. Ruggieri F., Marín V., Gimeno D., Fernandez-Turiel J.L., García-Valles M., Gutierrez L. Application of zeolitic volcanic rocks for arsenic removal from water. Engineering Geology 2008, 101:245-250.
261. Ruiping L., Lihua S., Jiuhui Q., Guibai L. Arsenic removal through adsorption, sand filtration and ultrafiltration: in situ precipitated ferric and manganese binary oxides as adsorbents. Desalination 2009, 249:1233-1237.
262. Runnells D.D., Wahli C. In situ electromigration as a method for removing sulfate, metals, and other contaminants from ground water. Ground Water Monitoring & Remediation 1993, 13:121-129.
263. Saalfield S.L., Bostick B.C. Changes in iron, sulfur, and arsenic speciation associated with bacterial sulfate reduction in ferrihydrite-rich systems. Environmental Science & Technology 2009, 43:8787-8793.
264. Sahu J.N., Acharya J., Meikap B.C. Response surface modeling and optimization of chromium(VI) removal from aqueous solution using tamarind wood activated carbon in batch process. Journal of Hazardous Materials 2009, 172:818-825.
265. Sahu J.N., Agarwal S., Meikap B.C., Biswas M.N. Performance of a modified multi-stage bubble column reactor for lead(II) and biological oxygen demand removal from wastewater using activated rice husk. Journal of Hazardous Materials 2009, 161:317-324.
266. Sahu J.N., Acharya J., Meikap B.C. Optimization of production conditions for activated carbons from tamarind wood by zinc chloride using response surface methodology. Bioresource Technology 2010, 101:1974-1982.
267. Salati S., Quadri G., Tambone F., Adani F. Fresh organic matter of municipal solid waste enhances phytoextraction of heavy metals from contaminated soil. Environmental Pollution 2010, 158:1899-1906.
268. Salt D.E., Blaylock M., Kumar N.P.B.A., Dushenkov V., Ensley B.D., Chet I., Raskin I. Phytoremediation: a novel strategy for the removal of toxic metals from the environment using plants. Nature Biotechnology 1995, 13:468-474.
269. Sang Y., Gu Q., Sun T., Li F., Liang C. Filtration by a novel nanofiber membrane and alumina adsorption to remove copper(II) from groundwater. Journal of Hazardous Materials 2008, 153:860-866.
270. Sang Y., Li F., Gu Q., Liang C., Chen J. Heavy metal-contaminated groundwater treatment by a novel nanofiber membrane. Desalination 2008, 223:349-360.
271. Santona L., Castaldi P., Melis P. Evaluation of the interaction mechanisms between red muds and heavy metals. Journal of Hazardous Materials 2006, 136:324-329.
272. Sas-Nowosielska A., Kucharski R., Malkowski E., Pogrzeba M., Kuperberg J.M., Krynski K. Phytoextraction crop disposal-an unsolved problem. Environmental Pollution 2004, 128:373-379.
273. Sastre J., Hernández E., Rodríguez R., Alcobé X., Vidal M., Rauret G. Use of sorption and extraction tests to predict the dynamics of the interaction of trace elements in agricultural soils contaminated by a mine tailing accident. Science of the Total Environment 2004, 329:261-281.
274. Satyawali Y., Schols E., Van Roy S., Dejonghe W., Diels L., Vanbroekhoven K. Stability investigations of zinc and cobalt precipitates immobilized by in situ bioprecipitation (ISBP) process. Journal of Hazardous Materials 2010, 181:217-225.
275. Satyawali Y., Seuntjens P., Van Roy S., Joris I., Vangeel S., Dejonghe W., Vanbroekhoven K. The addition of organic carbon and nitrate affects reactive transport of heavy metals in sandy aquifers. Journal of Contaminant Hydrology 2011, 123:83-93.
276. Say R., Denizli A., Yakup ArIca M. Biosorption of cadmium(II), lead(II) and copper(II) with the filamentous fungus Phanerochaete chrysosporium. Bioresource Technology 2001, 76:67-70.
277. Scherer M.M., Richter S., Valentine R.L., Alvarez P.J.J. Chemistry and microbiology of permeable reactive barriers for in situ groundwater clean up. Critical Reviews in Environmental Science and Technology 2000, 30:363-411.
278. Schirmer M., Butler B.J. Transport behaviour and natural attenuation of organic contaminants at spill sites. Toxicology 2004, 205:173-179.
279. Scholz R.W., Schnabel U. Decision making under uncertainty in case of soil remediation. Journal of Environmental Management 2006, 80:132-147.
280. Schwarzenbach R.P., Gschwend P.M., Imboden D.M. Environmental Organic Chemistry 1993, John Wiley, New York, NY.
281. Scullion J. Remediating polluted soils. Naturwissenschaften 2006, 93:51-65.
282. Seaman J.C., Bertsch P.M., Schwallie L. In situ Cr(VI) reduction within coarse-textured, oxide-coated soil and aquifer systems using Fe(II) solutions. Environmental Science & Technology 1999, 33:938-944.
283. Seki K., Thullner M., Hanada J., Miyazak T. Moderate bioclogging leading to preferential flow paths in biobarriers. Ground Water Monitoring & Remediation 2006, 26:68-76.
284. Sen Gupta B., Chatterjee S., Rott U., Kauffman H., Bandopadhyay A., DeGroot W., Nag N.K., Carbonell-Barrachina A.A., Mukherjee S. A simple chemical free arsenic removal method for community water supply - a case study from West Bengal, India. Environmental Pollution 2009, 157:3351-3353.
285. Sevougian S.D., Steefel C.I., Yabusaki S.B. Enhancing the Design of in Situ Chemical Barriers with Multicomponent Reactive Transport Modeling, in Situ Remediation: Scientific Basis for Current and Future Technologies. Proceedings of the 33rd Hanford Symposium on Health and the Environment 1994, Battelle Press, Columbus, OH, Pasco, Washington.
286. Sherwood L.J., Qualls R.G. Stability of phosphorus within a wetland soil following ferric chloride treatment to control eutrophication. Environmental Science & Technology 2001, 35:4126-4131.
287. Shiba S., Hirata Y. In-situ electrokinetic remediation of groundwater contaminated by heavy metal. Developments in Water Science 2002, 883-890. Elsevier. S. Majid Hassanizadeh, R.J. Schotting, W.G. Gray, F.P. George (Eds.).
288. Shiba S., Hirata Y., Seno T. Mathematical model for hydraulically aided electrokinetic remediation of aquifer and removal of nonanionic copper. Engineering Geology 2005, 77:305-315.
289. Sikdar S.K., Grosse D., Rogut I. Membrane technologies for remediating contaminated soils: a critical review. Journal of Membrane Science 1998, 151:75-85.
290. Silverberg B.A., Wong P.T.S., Chau Y.K. Localization of selenium in bacterial cells using TEM and energy dispersive X-ray analysis. Archives of Microbiology 1976, 107:1-6.
291. Sims R.C. Soil Remediation Techniques at Uncontrolled Hazardous Waste Sites 1990, Utah State University, pp. 704-732.
292. Singh T.S., Pant K.K. Solidification/stabilization of arsenic containing solid wastes using portland cement, fly ash and polymeric materials. Journal of Hazardous Materials 2006, 131:29-36.
293. Singh C.K., Sahu J.N., Mahalik K.K., Mohanty C.R., Mohan B.R., Meikap B.C. Studies on the removal of Pb(II) from wastewater by activated carbon developed from tamarind wood activated with sulphuric acid. Journal of Hazardous Materials 2008, 153:221-228.
294. Sirkar K.K. Membrane separation technologies: current developments. Chemical Engineering Communications 1997, 157:145-184.
295. Smedley P.L., Kinniburgh D.G. A review of the source, behaviour and distribution of arsenic in natural waters. Applied Geochemistry 2002, 17:517-568.
296. Smith L.A., Means J.L., Chen A., Alleman B., Chapman C.C., Tixier J.S., Brauning S.E.J., Gavaskar A.R., Royer M.D. Remedial Options for Metals-contaminated Sites 1995, Lewis Publishers, Boca Raton, FL.
297. Sneddon I.R., Garelick H., Valsami-Jones E. An investigation into arsenic(V) removal from aqueous solutions by hydroxylapatite and bone-char. Mineralogical Magazine 2005, 69:769-780.
298. Srivastava P.K., Vaish A., Dwivedi S., Chakrabarty D., Singh N., Tripathi R.D. Biological removal of arsenic pollution by soil fungi. Science of the Total Environment 2011, http://dx.doi.org/10.1016/j.scitotenv.2011.03.002.
299. Su C., Puls R.W. Arsenate and arsenite removal by zerovalent iron: kinetics, redox transformation, and implications for in situ groundwater remediation. Environmental Science & Technology 2001, 35:1487-1492.
300. Su C., Puls R.W. In situ remediation of arsenic in simulated groundwater using zerovalent iron: laboratory column tests on combined effects of phosphate and silicate. Environmental Science & Technology 2003, 37:2582-2587.
301. Sud D., Mahajan G., Kaur M.P. Agricultural waste material as potential adsorbent for sequestering heavy metal ions from aqueous solutions - a review. Bioresource Technology 2008, 99:6017-6027.
302. Sullivan C., Tyrer M., Cheeseman C.R., Graham N.J.D. Disposal of water treatment wastes containing arsenic - a review. Science of the Total Environment 2010, 408:1770-1778.
303. Sun H., Wang L., Zhang R., Sui J., Xu G. Treatment of groundwater polluted by arsenic compounds by zero valent iron. Journal of Hazardous Materials 2006, 129:297-303.
304. Suthersan S.S. Remediation Engineering: Design Concepts 1997, Lewis Publishers, New York.
305. Sylvester P., Westerhoff P., Möller T., Badruzzaman M., Boyd O. A hybrid sorbent utilizing nanoparticles of hydrous iron oxide for arsenic removal from drinking water. Environmental Engineering Science 2007, 24:104-112.
306. Tabakci M., Erdemir S., Yilmaz M. Preparation, characterization of cellulose-grafted with calix[4]arene polymers for the adsorption of heavy metals and dichromate anions. Journal of Hazardous Materials 2007, 148:428-435.
307. Tessier A., Campbell P.G.C., Bisson M. Sequential extraction procedure for the speciation of particulate trace metals. Analytical Chemistry 1979, 51:844-851.
308. Thiruvenkatachari R., Vigneswaran S., Naidu R. Permeable reactive barrier for groundwater remediation. Journal of Industrial and Engineering Chemistry 2008, 14:145-156.
309. Thornton E.C., Amonette J.E. Hydrogen sulfide gas treatment of Cr(VI)-contaminated sediment samples from a plating-waste disposal site implications for in-situ remediation. Environmental Science & Technology 1999, 33:4096-4101.
310. Thornton E.C., Jackson R.L. Laboratory and Field Evaluation of the Gas Treatment Approach for in Situ Remediation of Chromate-contaminated Soils 1994, prepared for the, Department of Energy, USA.
311. Till B.A., Weathers L.J., Alvarez P.J.J. Fe(0)-supported autotrophic denitrification. Environmental Science and Technology 1998, 32:634-639.
312. Tokunaga S., Park S.W., Ulmanu M. Extraction behaviour of metallic contaminants and soil constituents from contaminated soils. Environmental Technology 2005, 26:673-682.
313. Torres, L.G., Lopez, R.B., Beltran, M. Removal of As, Cd, Cu, Ni, Pb, and Zn from a highly contaminated industrial soil using surfactant enhanced soil washing. Physics and Chemistry of the Earth, Parts A/B/C. In Press, Corrected Proof, doi:10.1016/j.pce.2011.1002.1003.
314. Tuin B.J.W., Senden M.M.G., Tels M. Extractive cleaning of heavy metal contaminated clay soils. Environmental Technology: Proceedings of the Second European Conference on Environmental Technology 1987, M. Nijhoff Publisher, Dordrecht, Amsterdam, The Netherlands. K.J.A. DeWaal, W.J. van den Brink (Eds.).
315. Tuttle J.H., Dugan P.R., Randles C.I. Microbial sulfate reduction and its potential utility as an acid mine water pollution Abatement procedure. Applied and Environmental Microbiology 1969, 17:297-302.
316. Subsurface Contaminants Focus Area Report, (08/96) DOE/EM-0296 1996, USDOE, Office of Science and Technology, Springfield, VA.
317. Evaluation of Groundwater Extraction Remedies 1989, USEPA, EPA Offi{ligature}ce of Emergency and Remedial Responses, Washington, DC.
318. Vitrification Technologies for Treatment of Hazardous and Radioactive Waste. Handbook EPA/625/R-92/002 1992, USEPA, U.S. Environmental Protection Agency, Office of Research and Development, Washington, D.C.
319. How to Evaluate Alternative Clean up Technologies for Underground Storage Tank Sites. Offi{ligature}ce of Solid Waste and Emergency Response 1995, USEPA, US Environmental Protection Agency, Washington, DC., EPA 510-B-95-007.
320. Recent Developments for in Situ Treatment of Metal Contaminated Soils, 68-W5-0055 1997, USEPA.
321. Permeable Reactive Barrier Technologies for Contaminant Remediation, EPA 600/R-98/125, Washington, DC 20460, pp. 94 1998, USEPA.
322. van Halem D., Olivero S., de Vet W.W.J.M., Verberk J.Q.J.C., Amy G.L., van Dijk J.C. Subsurface iron and arsenic removal for shallow tube well drinking water supply in rural Bangladesh. Water Research 2010, 44:5761-5769.
323. van Houten R.T., Pol L.W.H., Lettinga G. Biological sulphate reduction using gas-lift reactors fed with hydrogen and carbon dioxide as energy and carbon source. Biotechnology and Bioengineering 1994, 44:586-594.
324. Van Nooten T., Springael D., Bastiaens L. Positive impact of microorganisms on the performance of laboratory-scale permeable reactive iron barriers. Environmental Science & Technology 2008, 42:1680-1686.
325. Vangronsveld J., Van Assche F., Clijsters H. Reclamation of a bare industrial area contaminated by non-ferrous metals: in situ metal immobilization and revegetation. Environmental Pollution 1995, 87:51-59.
326. Vidic R.D., Pohland F.G. Treatment Walls, Technology Evaluation Report TE-96-01 1996, Ground-Water Remediation Technologies Analysis Center, Pittsburgh, PA.
327. Vilensky M.Y., Berkowitz B., Warshawsky A. In situ remediation of groundwater contaminated by heavy- and transition-metal ions by selective ion-exchange methods. Environmental Science & Technology 2002, 36:1851-1855.
328. Villaescusa I., Fiol N., Martínez M., Miralles N., Poch J., Serarols J. Removal of copper and nickel ions from aqueous solutions by grape stalks wastes. Water Research 2004, 38:992-1002.
329. Virkutyte J., Sillanpää M., Latostenmaa P. Electrokinetic soil remediation - critical overview. The Science of the Total Environment 2002, 289:97-121.
330. WHO, 2000. Hazardous Chemicals in Human and Environmental Health: a Resource Book for School, College and University Students, in: Organisation, W.H. (Ed.), Geneva.
331. Wait S.T., Thomas D. The Characterization of Base Oil Recovered From the Low Temperature Thermal Desorption of Drill Cuttings. SPE/EPA Exploration and Production Environmental Conference, San Antonio, TX 2003, 151-158.
332. Walker W.J., Pucik-Ericksen L.E. In Situ Reduction of Hexavalent Chromium in Groundwater and Surface Soil Using Acidified Ferrous Sulfate. Abiotic In Situ Technologies for Groundwater Remediation Conference Proceedings, US EPA/625/R-99/012, Dallas, Texas 2000.
333. Wang S., Mulligan C. Rhamnolipid foam enhanced remediation of cadmium and nickel contaminated soil. Water, Air, &; Soil Pollution 2004, 157:315-330.
334. Wang S., Zhao X. On the potential of biological treatment for arsenic contaminated soils and groundwater. Journal of Environmental Management 2009, 90:2367-2376.
335. Wang X.S., Li Z.Z., Tao S.R. Removal of chromium (VI) from aqueous solution using walnut hull. Journal of Environmental Management 2009, 90:721-729.
336. Warren G.P., Alloway B.J., Lepp N.W., Singh B., Bochereau F.J.M., Penny C. Field trials to assess the uptake of arsenic by vegetables from contaminated soils and soil remediation with iron oxides. The Science of the Total Environment 2003, 311:19-33.
337. Warshawsky A., Strikovsky A.G., Vilensky M.Y., Jerabek K. Interphase mobility and migration of hydrophobic organic metal extractant molecules in solvent-impregnated resins. Separation Science and Technology 2002, 37:2607-2622.
338. Waybrant K.R., Blowes D.W., Ptacek C.J. Selection of reactive mixtures for use in permeable reactive walls for treatment of mine drainage. Environmental Science & Technology 1998, 32:1972-1979.
339. Waybrant K.R., Ptacek C.J., Blowes D.W. Treatment of mine drainage using permeable reactive Barriers: column experiments. Environmental Science & Technology 2002, 36:1349-1356.
340. Wilkin R.T., McNeil M.S. Laboratory evaluation of zero-valent iron to treat water impacted by acid mine drainage. Chemosphere 2003, 53:715-725.
341. Wilkin R.T., Puls R.W., Sewell G.W. Long-term Performance of Permeable Reactive Barriers Using Zero-Valent Iron: An Evaluation at Two Sites, EPA Environmental Research Brief; EPA/600/S-02/001 2002, U.S. Government Printing Office, Washington, DC.
342. Wilkin R.T., Acree S.D., Ross R.R., Beak D.G., Lee T.R. Performance of a zerovalent iron reactive barrier for the treatment of arsenic in groundwater: Part 1. Hydrogeochemical studies. Journal of Contaminant Hydrology 2009, 106:1-14.
343. Wilson B.H., Smith G.B., Rees J.F. Biotransformations of selected alkylbenzenes and halogenated aliphatic hydrocarbons in methanogenic aquifer material: a microcosm study. Environmental Science & Technology 1986, 20:997-1002.
344. Witt M.E., Klecka G.M., Lutz E.J., Ei T.A., Grosso N.R., Chapelle F.H. Natural attenuation of chlorinated solvents at Area 6, Dover Air Force Base: groundwater biogeochemistry. Journal of Contaminant Hydrology 2002, 57:61-80.
345. Wrenn B. Enhanced Reductive Dechlorination through Biological Interaction with Zero-valent Iron. Federal Remediation Technologies Roundtable Meeting, Arlington, Virginia, USA 2004.
346. Wu S.C., Cheung K.C., Luo Y.M., Wong M.H. Effects of inoculation of plant growth-promoting rhizobacteria on metal uptake by Brassica juncea. Environmental Pollution 2006, 140:124-135.
347. Xenidis A., Stouraiti C., Papassiopi N. Stabilization of Pb and As in soils by applying combined treatment with phosphates and ferrous iron. Journal of Hazardous Materials 2010, 177:929-937.
348. Xu Y., Zhang J., Qian G., Ren Z., Xu Z.P., Wu Y., Liu Q., Qiao S. Effective Cr(VI) removal from simulated groundwater through the hydrotalcite-derived adsorbent. Industrial & Engineering Chemistry Research 2010, 49:2752-2758.
349. Yang L., Shahrivari Z., Liu P.K.T., Sahimi M., Tsotsis T.T. Removal of trace levels of arsenic and selenium from aqueous solutions by calcined and uncalcined layered double hydroxides (LDH). Industrial & Engineering Chemistry Research 2005, 44:6804-6815.
350. Yang L., Donahoe R.J., Redwine J.C. In situ chemical fixation of arsenic-contaminated soils: an experimental study. Science of the Total Environment 2007, 387:28-41.
351. Yeung A.T., Hsu C.-n., Menon R.M. EDTA-Enhanced electrokinetic extraction of lead. Journal of Geotechnical Engineering 1996, 122:666-673.
352. Yeung A.T., Hsu C.-n., Menon R.M. Physicochemical soil-contaminant interactions during electrokinetic extraction. Journal of Hazardous Materials 1997, 55:221-237.
353. Yin Y., Allen H.E. In-situ Chemical Treatment. Technology Evaluation Report, TE-99-01 1999, Ground-Water Remediation Technologies Analysis Center, Pittsburg, PA.
354. Yong R.N., Mulligan C.N. Natural Attenuation of Contaminants in Soils 2004, CRC Press, Boca Raton (FL).
355. Yuan T., Hu J.Y., Ong S.L., Luo Q.F., Ng W.J. Arsenic removal from household drinking water by adsorption. Journal of Environmental Science and Health, Part A: Toxic/Hazardous Substances and Environmental Engineering 2002, 37:1721-1736.
356. Yuan S., Wu C., Wan J., Lu X. In situ removal of copper from sediments by a galvanic cell. Journal of Environmental Management 2009, 90:421-427.
357. Zelina J.P., Rusling J.F. Electrochemical remediation of soils. Encyclopedia of Environmental Pollution and Cleanup 1999, 11:532-539.
358. Zhang W., Tsang D.C.W., Lo I.M.C. Removal of Pb and MDF from contaminated soils by EDTA- and SDS-enhanced washing. Chemosphere 2007, 66:2025-2034.
359. Zhang W., Tsang D.C.W., Lo I.M.C. Removal of Pb by EDTA-washing in the presence of hydrophobic organic contaminants or anionic surfactant. Journal of Hazardous Materials 2008, 155:433-439.
360. Zhang W., Tong L., Yuan Y., Liu Z., Huang H., Tan F., Qiu R. Influence of soil washing with a chelator on subsequent chemical immobilization of heavy metals in a contaminated soil. Journal of Hazardous Materials 2010, 178:578-587.