Traitabilité des sols pollués - · PDF fileRéférences...

Traitabilité des sols polluésGuide méthodologique pour la sélection des techniques

et l’évaluation de leurs performances

REFERENCES BIBLIOGRAPHIQUES

Références bibliographiques 3

Références bibliographiques

Références générales sur la méthodologie

Littérature citée

[1] Ministère de l'écologie et du développement durable, Gestion des sites (potentiellement) pollués – Version 2, Ed BRGM, 2000

[2] Ministère de l'écologie et du développement durable, Guide méthodologique pour l'analyse des sols pollués, Ed BRGM, 2001, 83 p.

Pour en savoir plus

Ministère de l'écologie et du développement durable, Gestion des sites pollués – Version 0, Ed BRGM, 2000

Ministère de l'écologie et du développement durable, Guide sur le comportement des polluants dans le sol et les nappes, Ed BRGM, 2001, 119 p.

Références générales sur les polluants

Littérature citée

[3] Verschueren, K. (1996). Handbook of environmental data on organic chemicals. Amsterdam, Pays Bas: Van Nostrand Reinhold. 2064 pages.

[4] Yaws CL (1999). Chemical Properties Handbook : physical, thermodynamic, environmental, transport, safety, and health related properties for organic and inorganic chemicals. McGraw-Hill (ed), New York.

Pour en savoir plus

Le Cloirec P. (1998). Les composés organiques (COV) dans l'environnement. Paris: Technique et Documentation. 734 pages.

Références générales sur les sols

Littérature citée

[5] Duchaufour, P.. Pédologie : Sol, Végétation, Environnement. 3ème édition. Paris : Masson, 1991, ISBN : 2-225-82421-5, 289 p.

Pour en savoir plus

Sparks, D. L (1995). Environmental soil chemistry. Londres, UK: Academic Press. 267 pages.


Références générales sur les traitements

Littérature citée

[6] Lecomte, P. (1995). Les sites pollués, traitement des sols et des eaux souterraines. Paris: Technique et Documentation. 198 pages.

Bibliographie thématique

Tris physiques ou physico-chimiques (technique n°1)

Littérature citée

[7] Anderson R., Rasor E., Van Ryn F. (1999) – Particle size separation via soil washing to obtain volume reduction. Journal of Hazardous Materials – 66, pp. 89-98.

[8] Clozel B. et Legendre 1995 - Caractérisation minéralogique et cristallochimique de vitrifiats. Actes du congrès international sur les procédés de solidification et stabilisation des déchets. Nancy –

France. 28 nov.1er dec 1995. pp. 53-57.

[9] Hankel D., Rosenstock F., Biehler G. (1992) – The effect of attrition in the Lurgi-Deconterra process for decontamination of soil. Aufbereitungs Technik -33, n°5, pp. 257-265

[10] Mahé – Le Carlier C. 1997 – Caractérisation pétrographique et chimique d’analogues de déchets vitrifiés actuels : les scories de la métallurgie ancienne. Etude de l’altération naturelle et expérimentale. Thèse INPL Nancy, 337 p.

[11] Mann M.J. (1999) – Full-scale and pilot-scale soil washing. Journal of Hazardous Materials – 66, n° 1-2, pp. 119-136.

[12] Neesse Th., Grohs H. (1991) – Solid / liquid separation for waste management in soil washing plants. Aufbereitungs technik – n°32, pp. 294-302.

Pour en savoir plus

Bovendeur J., Visser B., Childs G. (1991) – The fingerprint method, a practical tool in linking characterisation and treatment of polluted dredged material. Proceed. Cats Congress on Characterisation and Treatment of Contaminated Dredged Material - pp. 5-16.

Bovendeur J., Mozley R.. (1993) – Characterisation and treatment of polluted material. Environmental application of mineral processing technology. Proceed. XVIII Int. Mineral Processing Congress – Sydney 23-28 May 1993, pp. 1267-1270.

Kuhlman M.I., Greenfield T.M. (1999) – Simplified soil washing processes for a variety of soils. Journal of Hazardous Materials – 66, pp. 31-45.

Neesse Th. (1990) – Wet processing of contaminated soils. Aufbereitungs technik – n°31, pp. 563-569.

Neesse Th., Feil A. (1993) – The decontamination characteristic of polluted soils for assessment of suitability for treatment of former industrial sites. Aufbereitungs technik – n°34, pp. 27-35.

Williford C.W., Li Z., Wang Z., Bricka R.M. (1999) – Vertical column hydroclassification of metal-contaminated soils. Journal of Hazardous Materials – 66, n° 1-2, pp. 15-30.


Lavage par agents chimiques ou tensio-actifs (technique n°2)

Littérature citée

[13] Chauzy J. et al (1999) – Traitement des sols pollués par le chrome : mise en œuvre d'un nouveau procédé par extraction chimique. L'eau, l'industrie, les nuisances – n°220, pp. 60-64.

[14] Cornu S., Clozel B. (2000) : Extractions séquentielles et spéciation des éléments trace métalliques dans les sols naturels : analyse critique - Etude et Gestion des Sols, 7, 3, pp. 179-189

[15] Daus B., Weiss H., Wennrich R. (1998) - Arsenic speciation in iron hydroxyde precipitates. Talanta 46 (1998) 867-873.

[16] Guyard Ch. (1999) – Dépollution des sols : une palette de procédés pour des cas toujours particuliers. L'eau, l'industrie, les nuisances – n°220, pp. 37-49.

[17] Juillot F. (1998) – Localisation et spéciation de l’arsenic, du plomb et du zinc dans des sites et sols contaminés. Comparaison avec un sol développé sur une anomalie géochimique naturelle en plomb. Thèse Univ. Paris VII, 229 p.

[18] Laperche V., Logan T.J., Gaddam P., Traina S.J. 1997 – Effect of apatite amendments on plant uptake of lead from contaminated soil. Environ. Sci. Technol. 31 : 2745-2753.

[19] Ma L.Q., Choate A.L., Rao G.N., 1997 – Effects of incubation and phosphate rock on lead extractability and speciation in contaminated soils. J. Environ. Qual. 26 :801-807

[20] Matera V. (2001) -Etude de la mobilité et de la spéciation de l'arsenic dans les sols de sites industriels pollués : estimation du risque induit- Thèse Pau 27/04/2001

[21] Mazza J., Jacobson P. (1993) – Treatability of PCBs and PAHs in dredged riverbed sediments adjacent to an aluminium manufacturing facility. Extraction and processing for the treatment and minimization of wastes, Hager J. ed. – pp. 499-508.

[22] Morin, G. , Juillot F. , Lecocq D., Calas G., Ildefonse P. (2000) - Cristallochimie de l’arsenic et mesures directes de sa spéciation dans les environnements de surface - à paraître dans Actes du Séminaire de la Société de l'Industrie Minérale, Narbonne, 28-29 septembre 2000 (sous presse)

[23] Papassiopi N., Tambouris S., Kontopoulos A. (1999) – Removal of heavy metals from calcareous contaminated soils by EDTA leaching. Water, air and soil pollution – n°1-4, 109, pp. 1-15.

[24] Peters R.W. (1999) – Chelant extraction of heavy metals from contaminated soils. Journal of Hazardous Materials – 66, n° 1-2, pp. 151-210.

[25] Pierce M.L. and Moore C.B. (1980) – Adsorption of arsenite on amorphous iron hydroxide from dilute aqueous solution. Environ. Sci. Technol. 14, 214-216.

[26] Saada A., Gauthier S., Gaboriau H., Conil P., 1999. Impact of humic acids on polycyclic aromatic hydrocarbon retention by soils. Proc. European Union of Geoscience, 28 march- 1 april 1999, (EUG 10 / L03.2988).

[27] Tessier A., Campbell P., Bisson M. (1979). Sequencial extraction procedure for the speciation of particulate trace metals. Analytical Chemistry, 51, 7, pp. 844-851.

[104] Bettahar M., Ducreux J., Schäfer G., et Van Dorpe F.,, 1999. « Surfactant Enhanced In Situ Remediation of LNAPL Contaminated Aquifer : Large Scale Studies on a Controlled Experimental Site », Transport in Porous Media 37 : pp 255-276. Kluwer Academic Publishers.


Pour en savoir plus

Bartlett R.W. (1993) – Soil decontamination by percolation leaching. Extraction and processing for the treatment and minimization of wastes, Hager J. ed. – pp. 411-424.

Clifford S.R. (1993) – Removal of organic contamination from Buffalo River sediment by froth flotation. Minerals and Metallurgical Processing, november, pp. 195-199.

Dupuy-Kedziorek, 1997 – Mobilité naturelle et provoquée de polluants métalliques dans les sols et les sédiments. Thèse de l’Université de Limoges. 126 pages.

Elliott H.A., Shastri N.L. (1999) – Extractive decontamination of metal-polluted soils using oxalate. Water, Air and Soil Pollution - 110, pp. 335-346.

Ghestem J.P.- 1997 – Extraction par l’EDTA de métaux traces de sols pollués ; application à l’étude de la faisabilité d’une spéciation de ces métaux. Thèse de l’Université Paris XII. 157 pages.

Wavrer.P., Lecomte.P., Vedrine.H. (1998) Sampling and heterogeneity of polluted soils: the error assessment., in CONSOIL 98 - International FZK/TNO Conference on Contaminated Soil 6th - May 17-21 - 1998 Edinburgh - United Kingdom, p. 827-828

Wavrer.P. (1997) Apport à la théorie de l'échantillonnage des solides hétérogènes. Application à des grandeurs mesurées sur matières premières, secondaires et ultimes., Documents BRGM, Orléans : Editions BRGM, N° 265, 211 p

Lavage par agents tensio-actifs

AATDF, 1997. “Technology Practices Manual for Surfactants and Cosolvents”, Technical Report, Document No. TR-97-2.

EPA, 1991. “In Situ Soil Flushing”, Engineering Bulletin, EPA/540/2-91/021.

EPA, 1994. “In Situ Remediation Technology Status Report: Cosolvent”, Engineering Bulletin, EPA/542/K-94/006.

EPA, 1996. “A Citizen's Guide to In Situ Soil Flushing”, Technology Fact Sheet, EPA/542/F- 96/006.

EPA, 1997. “Best Management Practices (BMPs) for Soil Treatment Technologies: Suggested Operational Guidelines to Prevent Cross-media Transfer of Contaminants During Clean-UP Activities”, EPA OSWER, EPA/530/R-97/007.

Nash J., R.P. Traver, and D.C. Downey, 1986. "Surfactant-Enhanced In Situ Soils Washing", USAF Engineering and Services Laboratory, Florida. ESL-TR-97-18, Available from NTIS, Springfield, VA, Order No. ADA188066.

Sturges, S.G., Jr., P. McBeth, Jr., R.C. Pratt, 1992. "Performance of Soil Flushing and Groundwater Extraction at the United Chrome Superfund Site," Journal of Hazardous Materials, El Savior Science Pub., B.V., Amsterdam, Vol. 29, pp. 59-78.

“Surfactants and Cosolvents for NAPL Remediation” A Technology Practices Manual (Aatdf Monograph Series.) (Hardcover) by Donald F. Lowe (Author), Carroll L. Oubre (Author), C. H. Ward (Author) "In 1993, the Department of Defense (DOD) funded the Advanced Applied Technology Demonstration Facility (AATDF) at Rice University to advance innovative technologies for the remediation..."

Nash J., R.P. Traver, and D.C. Downey, 1986. "Surfactant-Enhanced In Situ Soils Washing", USAF Engineering and Services Laboratory, Florida. ESL-TR-97-18, Available from NTIS, Springfield, VA, Order No. ADA188066.


Bettahar M., Ducreux J., Schäfer G., et Van Dorpe F.,, 1999. « Surfactant Enhanced In Situ Remediation of LNAPL Contaminated Aquifer : Large Scale Studies on a Controlled Experimental Site », Transport in Porous Media 37 : pp 255-276. Kluwer Academic Publishers.

Mackay AA., Chin YP., Macfarlane JK., and Gschwend PM., 1996 “Laboratory Assessment of BTEX Soil Flushing” Environmental Science & Technology, 1996, pp 3223-3231.

Soil flushing

EPA, 1991. “In Situ Soil Flushing”, Engineering Bulletin, EPA/540/2-91/021.

EPA, 1994. “In Situ Remediation Technology Status Report: Cosolvent”, Engineering Bulletin, EPA/542/K-94/006.

EPA, 1996. “A Citizen's Guide to In Situ Soil Flushing”, Technology Fact Sheet, EPA/542/F-96/006.

EPA, 1997. “Best Management Practices (BMPs) for Soil Treatment Technologies: Suggested Operational Guidelines to Prevent Cross-media Transfer of Contaminants During Clean-UP Activities”, EPA OSWER, EPA/530/R-97/007.

Sang-Woo L., Ju-Yong K., Jong-Un L., Ilwong K., and Kyoung-Woong K. 2003.”Removal of arsenic in tailings by soil flushing and the remediation process monitoring” Environmental Geochemistry and Health 26; pp 403-409. Kluwer Academic Publishers 2004.

Sturges, S.G., Jr., P. McBeth, Jr., R.C. Pratt, 1992. "Performance of Soil Flushing and Groundwater Extraction at the United Chrome Superfund Site," Journal of Hazardous Materials, El Savior Science Pub., B.V., Amsterdam, Vol. 29, pp. 59-78.

Wagner C., Pflugbeil K, Henning K.: “Untersuchungen zur Wirkungsweise von definierten Tensiden auf ausgewählte Schadstoffe bei der Sanierung von Böden. Abschlussbericht der IfE Leipzig GmbH, im Auftrag des Bundesministeriums für Wirtschaft, Reg.-Nr 566/93, 1994.

Wagner C., Pflugbeil K, Henning K.: “In situ Bodensanierung unter Verwendung von Tensiden. Abschlussbericht des Institutes für Energetik und Umwelt GmbH, im Auftrag des Bundesministeriums für Wirtschaft, Reg. – Nr 521/94, 1995.

Wagner C., Pflugbeil K, Henning K.: “In situ Bodensanierung unter Verwendung von Tensiden “Présentation au 11 ème colloque DECHEMA-Fachgesprächs Umweltschutz “In situ Sanierung von Böden” 1996. DECHEMA e.V, ISBN 3-926959-72-X, pp.269-276.

Allison A. MacKay, Yu-Ping Chin, John K. MacFarlane, and Philip M. Gschwend “ Laboratory Assessment of BTEX Soil Flushing “ Department of Civil and Environmental Engineering, Ralph M. Parsons Laboratory, 48-415, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, and Department of Geological Sciences, The Ohio State University, Columbus, Ohio 43210 . Received: December 29, 1995 .Revised June 1, 1996. Accepted June 2, 1996.

Shai Arnona, b, ,Zeev Ronena, , Alexander Yakirevicha, and Eilon Adara, b : “Evaluation of soil flushing potential for clean-up of desert soil contaminated by industrial wastewater”, Chemosphere , Volume 62, Issue 1, January 2006, Pages 17-25.

L. Di Palma : “Experimental Assessment of a Process for the Remediation of Organophosphorous Pesticides Contaminated Soils Through In Situ Soil Flushing and Hydrolysis” Water, Air, & Soil Pollution , Publisher Springer Netherlands ,ISSN 0049-6979 (Print) 1573-2932 (Online) ,Issue Volume 143, Numbers 1-4 / February, 2003 ,DOI 0.1023/A:1022890529765 , Pages 301-314

EPA 542-R-97-004, Recent Developments for In Situ Treatment of Metal Contaminated Soils (PDF) (64 pp, 561K).

Uhlig U., Tränckner S., Luckner L., Waldemar H., DGFZ e.V Dresden (RFA) “Neues Verfahren zur In situ Alkoholwâsche eines mit LNAPL kontaminierten Untergrundes”, DECHEMA “In situ Sanierung, Trends in Forschung und Praxis” November 2004, Tagungshandbuch , pp. 108-110


Koschitzky H.P, Braun J., Greiner P., Hiester U., Trötschler O., Universität Stuttgart, VEGAS (RFA) “Innovative thermische und Spûll-Verfahren zur In situ Sanierung”, DECHEMA “In situ Sanierung, Trends in Forschung und Praxis” November 2004, Tagungshandbuch , pp. 31-35.

Handbuch Altlasten “Handbuch Bodenwäsche” Landesamt für Umwelt LfU Baden Württtemberg, 1993.

Handbuch Altlasten und Grundwasserschadensfälle “Hydraulische und pneumatische in situ Verfahren” Landesamt für Umwelt LfU Baden Württtemberg, 1995.


Extraction sous pression réduite et extraction multiphasique (technique n°3)

Littérature citée

[6] Lecomte, P. (1995). Les sites pollués, traitement des sols et des eaux souterraines. Paris: Technique et Documentation. 198 pages.

[28] Applegate, J., Gentry, J.K., Malot, J..J. Vacuum Extraction of hydrocarbons from subsurface soils at a gasoline contamination site. Proceedings of the 8th national conference of uncontrolled hazardous wastes Superfund’ 87 : Washington, D.C., 1987. p. 273-278.

[29] Connor, J.R. Case study of soil venting. Pollution engineering, 1988, vol 20, n°8, p.74-78.

[30] Pedersen, T.A., Soil Vapor Extraction Technology : Reference Handbook. Cincinnati, USA : Risk Reduction Engineering Laboratory, Office of Research and Development, USEPA. 1991. 316 p.

[31] Pedersen, T.A.,Curtis, J.T. Pollution Technology review n°204 : Soil Vapor Extraction Technology. Park Ridge, N.J., USA : Noyes Data Corporation, 1991. 316 p.

[105] U.S. Environmental Protection Agency. How to Evaluate Alternative Cleanup Technologies for Underground Storage Tank Sites: A Guide for Corrective Action Plan Reviewers. EPA 510-B-94-003; EPA 510-B-95-007; and EPA 510-R-04-002. May 2004.

[106] U.S. Army Corps of Engineers. Engineer Manual. Multi-Phase Extraction, Engineering and Design. EM 1110-1-4010. June 1999.

[107] U.S. Environmental Protection Agency. Terra VAC In Situ Vacuum Extraction System Applications. Analysis Report. EPA-540-A5-89-003. July 1989.

[108] V.G. Kallur, J.G. Agar, T.T. Wong, J. Naus, A.P. Michielsen. Dual Phase Vacuum Extraction Technology for the recovery of petroleum hydrocarbon contamination from the subsurface – a case study. 56th Canadian Geotechnical Conference. 4th Joint IAH-CNC/CGS Conference. 2003 NAGS conference. 2003.

Pour en savoir plus

Anderson, C. W. (1994). Innovative site remediation technology vol.8 : Vacuum vapor extraction. Berlin: Springer Verlag. 224 pages.

Betz, C.; Färber, A.; Green, C.M.; Koschitzky, H.P.; Schmidt, R. Removing volatile and semi-volatile contaminants from the insatured zone by injection of a steam/air-mixture. Contaminated soil ‘98, Thomas Telford. London, 1998, p 575-584.

Bonila, A.; Cuesta, P.; Zubiaga, R.; Hierro, B. Hydrocarbons contaminated soil remediation using soil venting. Application of simulation models. Contaminated soil ‘98, Thomas Telford. London, 1998, p 1143-1144.

Fotinich, A., Dhir, V.K., Lingineni, S. Remediation of simulated soils contaminated with diesel. Journal of environmental engineering, 1998, vol 125, n°1, p 36-46.

Harper, B.M., Stiver, W.H., Zytner, R.G. Influence of water content on SVE in a silt loam soil. Journal of environmental engineering, 1998, vol 124, n°11, p 1047-1053.

Hutzler, N.J., Murphy, B.E., Gierke, J.S. Review of soil vapor extraction system technology. Technology review n°204 : Soil Vapor Extraction Tech nology. Park Ridge, N.J., USA : Noyes Data Corporation, 1991, p 136-162.


Koltuniak, D.L. In-situ air stripping cleans contaminated soil. Chemical engineering, 1986, vol 93, n°16, p 30-31.

Mahjoub, B. Comportement dans les sols de polluants aromatiques issus du goudron de houille. Etude du partage goudron/eau et de l’effet du vieillissement sur la mobilité des polluants. Thèse sciences et techniques du déchet : Institut national des sciences appliquées de Lyon, 1999. 262 p.

Malina, G., Grotenhuis, J.T.C., Rulkens, W.H., Mous, S.L.J., De Wit, J.C.M. Soil vapour extraction versus bioventing of toluene and decane in bench-scale soil columns. Environmental technology, 1998, vol 19, n°10, p 977-991.

Nadim, F., Nadim, A., Hoag, G.E., Dahmani, A.M. Desorption rate limitation in the extraction of organic molecules from unsatured soils during soil venting operations. Journal of contaminant hydrology, 1997, vol. 25, n°1-2, p. 21-37.

Risoul, V. Etude à l’échelle du laboratoire de l’influence de la pression sur la décontamination thermique de sols pollués par des molécules organiques. Etude particulière des hydrocarbures aromatiques polycycliques. Thèse science de l’ingénieur : Université de Haute-Alsace, 1998. 232 p.

Van Zutphen, M.; Heron, G.; Enfield, C.G.; Christensen, T.H. Resistive heating enhanced soil vapor extraction of chlorinated solvents from trichloroethylene contaminated silty, low permeable soil. Contaminated soil ‘98. Thomas Telford. London : 1998 ,p.561-570.

Extraction multiphasique

Carrie J Carter, William H DiGuiseppi. Dealing with DNAPLs. Civil Engineering, vol.68, No.11, pp. 46-48, Nov 1998.

David P. Bouchard, Todd M. Musterait, James A. Sobieraj. A Practical Approach to Steam-Enhanced Dual-Phase Extraction: A Case Study. Remediation summer 2003.

Hayes, Seay, Mattern & Mattern , Inc. REMOVAL OF PETROLEUM USING DUAL PHASE EXTRACTION.

U.S. Environmental Protection Agency. Analysis of Selected Enhancements for Soil Vapor Extraction. EPA-542-R-97-007. September, 1997b.

U.S. Environmental Protection Agency. Cleaning Up the Nation’s Waste Sites: Markets and Technology Trends; 1996 Edition. EPA 542-R-96-005. April, 1997a.

U.S. Environmental Protection Agency. Cost and Performance Report for LNAPL Recovery EPA 542-R-05-016. March, 2005.

U.S. Environmental Protection Agency. How to Effectively Recover Free Product at Leaking Underground Storage Tank Sites: A Guide for State Regulators, EPA 510-R-96-001. September, 1996.

U.S. Environmental Protection Agency. Multi-Phase Extraction : State of the Practice. EPA 542-R-99-004. June 1999.

U.S. Environmental Protection Agency. Presumptive Remedy: Supplemental Bulletin Multi-phase Extraction (MPE) Technology for VOCs in Soil and Groundwater. EPA 540-F-97-004. April, 1997c.


Désorption thermique (technique n°4)

Littérature citée

[32] US EPA (1997), Innovative SITE remediation Technology : Design and application, Thermal Desorption, Vol. 5, 9-1997

Pour en savoir plus

Antonini G., Gislais P., Traitement thermique des déchets industriels, Paris : Technique et Documentation, 1995, 141 p

Bucala V. ; Saito H.; Howard J.B.; Peters W.A. Thermal treatment of fuel oil-contaminated soils under rapid conditions. Environmental Science and Technology. 1997, vol 28, p 1801-1807.

Dutruch, L. Etude de la réticulation, du vieillissement et de la dégradation thermique de bisnadimides : Couplage analyse thermogravimétrique - chromatographie en phase gazeuse. Thèse matériaux macromoléculaires et composites : Université Claude Bernard Lyon 1, 1996, 163 p.

Gilot P.; Howard J.B.; Peters W.A. Evaporation phenomena during thermal decontamination of soils. Environmental Science and Technology. vol. 31, 1997, n°2; p 461-466.

Lighty J.S.; Pershing D.W.; Cundy V.A.; Linz D.G. Characterization of thermal desorption phenomena for the cleanup of contaminated soil. Nuclear and chemical waste management. 1988, vol 8, n°3, p 225-237.

Mc Lennen W.H.; Arnold N.S.; Robert K.A.; Meuzelaar H.L.C.; Lighty J.S.; Lindgren E.R. Fast, repetitive GC/MS analysis of thermally desorbed Polycyclic Aromatic Hydrocarbons (PAHs) from cantaminated soils. Combustion Science and Technology. 1990, vol 74, n°1-6, p 297-309

Nielson R.K.; Cosmos, M.G. Low temperature thermal treatment of volatile organic compounds from soil: A Technology demonstrated. Environmental progress. 1989, vol 8, n°2, p 139-142

Risoul, V. Etude à l’échelle du laboratoire de l’influence de la pression sur la décontamination thermique de sols pollués par des molécules organiques. Etude particulière des hydrocarbures aromatiques polycycliques. Thèse science de l’ingénieur : Université de Haute-Alsace, 1998. 232 p.

Struppe, H.G.; Franke, F.; Hofmann, J.; Ondruschka, B. Coupling of thermal desorption in modified closeable sampling columns with wide-bore capillary gas chromatography and mass spectrometric detection. Journal of chromatography, 1996, vol. 750, p 239-244.

Troxler W.L.; Cudahy J.J.; Zink R.P.; Yezzi, J.J., Rosenthal S.I. Treatment of nonhazardous petroleum-contaminated soils by thermal desorption technologies. Air and waste, vol 43, 1993, p 1512-1525.


Phytoextraction (technique n°5)

Littérature citée

[33] Baker, A.J.M., McGrath, S.P., Sidoli, C.M.D. et Reeves, R.D., 1994, The possibility of in situ heavy metal decontamination of polluted soils using crops of metal-accumulating plants, Resources Conservation and Recycling, 11: 41-49

[34] Boularbah, A., Bitton, G., Morel, J.L., et Schwartz, C. 2000. Assessment of metal accumulation in plants using MetPAD, a toxicity test specific for metal toxicity, Environmental Toxicology, 15 (5) : 449-455.

[35] Brown, S.L., Chaney, R.L., Angle, J.S. et Baker, A.J.M., 1994, Phytoremediation potential of Thlaspi caerulescens and Blader Campion for zinc- and cadmium-contaminated soil, Journal of Environmental Quality, 23: 1151-1157

[36] Echevarria G., Morel J.L., Fardeau J.C. et Leclerc-Cessac E., 1998. Assessment of phytoavailability of nickel in soils. Journal of Environmental Quality, 27:1064-1070.

[37] Escarré, J., Lefèbvre, C., Leblanc, M., Lepart, J. et Delay, B., 2000, Zinc and cadmium hyperaccumulation by Thlaspi caerulescens from metalliferous and nonmetalliferous sites in the mediterranean area : implications for phytoremediation, New Phytol., 145: 429-435

[38] Gérard E., Echevarria G., Sterckeman T. et Morel J.L., 2000. Availability of Cd to three plant species varying in accumulation pattern. Journal of Environmental Quality, 29:1117-1123.

[39] Jaffré, T., R.R. Brooks, J. Lee, and R.D. Reeves. 1976. Sebertia acuminata : a hyperaccumulator of nickel from New Caledonia. Science 193:579-580.

[40] Lombi, E., Zhao, F., McGrath, P., Young, S.D. et Sacchi, G.A., 2001, Physiological evidence for a high-affinity cadmium transporter highlyexpressed in a Thlaspi caerulescens ecotype, New Phytol., 149: 53-60

[41] McGrath, S.P., Sidoli, C.M.D., Baker, A.J.M. et Reeves, R.D., 1993, The potential for the use of metal-accumulating plants for the in situ remediation of metal-polluted soils, In: Integrated Soil and Sediment Research : A Basis for Proper Protection, H.J.P., E. et T., H., 673-676

[42] Meerts, P. et Van Isacker, N., 1997, Heavy metal tolerance and accumulation in metallicolous and non-metallicolous populations of Thlaspi caerulescens from continental Europe, Plant Ecology, 133: 221-231

[43] Perronnet, K, Schwartz, C., Gérard, E., et Morel, J.L. 2000. Availability of cadmium and zinc accumulated in the leaves of Thlaspi caerulescens incorporated into soil. Plant and Soil, 227 : 257-263.

[44] Reeves, R.D., Schwartz, C., Morel, J.L. et Edmondson, J., 2001, Distribution and metal-accumulating behaviour of Thlaspi caerulescens and associated metallophytes in France, Intern. J. of Phytoremediation, 3: 145-172

[45] Robinson, B.H., Leblanc, M., Petit, D., Brooks, R.R., Kirkman, J.H. et Gregg, P.E.H., 1998, The potential of Thlaspi caerulescens for phytoremediation of contaminated soils, Plant and Soil, 203: 47-56

[46] Schwartz, C., 1997, Phyoextraction des métaux des sols pollués par la plante hyperaccumulatrice Thlaspi caerulescens, Thèse de Doctorat de l'INPL, Nancy, 180p

[47] Schwartz, C., Echevarria, G., et Morel, J.L. 2002. Phytoextraction of cadmium with Thlaspi caerulescens. Plant and Soil, sous presse.

[48] Schwartz, C., Gérard, E., Perronnet, K., et Morel J.L., 2001. Measurement of in situ phytoextraction of zinc by spontaneous metallophytes growing on a former smelter site, The Science of the Total Environment, 279, 215-221.

[49] Schwartz, C., Guimont, S., Saison, C., Perronnet, K. et Morel, J.L. 2001. Phytoextraction of metals from polluted soils by the hyperaccumulator Thlaspi caerulescens. South African Journal of Science, 97, 561-564.


[50] Schwartz, C., Morel, J.L., Saumier, S., Withing, S.N. et Baker, A.J.M., 1999. Root architecture of the Zn-hyperaccumulator plant Thlaspi caerulescens as affected by metal origin, content and localisation in soil. Plant and Soil, 208, 103-115.

[51] Shallari, S., Schwartz, C., Hasko, A., et Morel, J.L. 1997. Heavy metals in soils and plants of serpentine and industrial sites of Albania. The Science of the Total Environment, 209, 133-142.

[52] Zhao, F., Hamon, R.E., Lombi, E., McLaughlin, M.J. et McGrath, P., 2002, Characteristics of cadmium uptake in two contrasting ecotypes of the hyperaccumulator Thlaspi caerulescens, J. Exp. Bot., 53(368): 535-543


Bio-lixiviation (technique n°6)

Littérature citée

[5] Duchaufour, P.. Pédologie : Sol, Végétation, Environnement. 3ème édition. Paris : Masson, 1991, ISBN : 2-225-82421-5, 289 p.

[20] Matera V. (2001) -Etude de la mobilité et de la spéciation de l'arsenic dans les sols de sites industriels pollués : estimation du risque induit- Thèse Pau 27/04/2001


[53] Baldi, F. ; Clark, T. ; Pollack, S.S. & Olson, J. Leaching of Pyrites of Various Reactivies by Thiobacillus ferrooxidans. Applied and Environmental Microbiology, 1992, Vol. 58, n°6, p. 1853-1856.

[54] Brierley,C.. Bacterial leaching. CRC Critical Reviews in Microbiology, 1978, VOL. 6, N° 3, P. 207-261.

[55] Brierley, J.A. & Leroux, N.W.. L’exploitation Microbiologique des Mines. Pour La Science, Octobre 1982, p. 38-53.

[56] Daus B., Weiss H., Wennrich R. (1998) - Arsenic speciation in iron hydroxyde precipitates. Talanta 46 (1998) 867-873.

[57] Funtowicz, N. Etude de l’oxydation bactérienne de composés soufrés en vue de l’application au traitement de sols pollués par des métaux. Thèse, 1995, INSA de Lyon, 95-ISAL0040, 215 p.

[58] Gupta S.K., Vollmer M.K., Krebs R.. The importance of mobile, mobilisable and pseudo-total heavy metal fractions in soil for three-level risk assessment and risk management. The Science of the Total Environment, (1996), 178, pp. 11-20.

[59] Haddadin, J.. Etudes cinétiques et microbiologiques de la lixiviation bactérienne en réacteurs : Effet de différents paramètres physico-chimiques, développement d’un procédé en réacteur Air-Lift et lit fluidisé et application à l’extraction de l’antimoine ; Thèse, 1995, Ecole Nationale Supérieure d’Agronomie et d’Industries Agro-Alimentaires (ENSAIA, Nancy), 249p.

[60] Harvey P.I. & Crundwell F.K.. Growth of Thiobacillus ferrooxidans: a novel experimental design for batch growth and bacterial leaching studies. Appl. Environ. Microbiol., 1997, Vol. 63 n°7 p. 2586-2592.

[61] Hutchins, S.R., Davidson, M.S., Brierley, J.A., & Brierley, C.L.. Microorganisms in reclamation of metals. Annu.Rev.Microbiol., 1986, 40, 311-336.

[62] Kostka, JE & Nealson, KH.. Dissolution and reduction of magnetite by bacteria. Environ. Sci. & Technol. (1995). 29, 2535-2540.

[63] Krebs, W. ; Brombacher, C. ; Bosshard, P.P. ; Bachofen, R. & Brandl, H.. Microbial Recovery of Metal from Solids. FEMS Microbiology Reviews, 1997, Vol., p. 605-617.

[64] Lovley, D.R.. Dissimilatory metal reduction. Annu.Rev.Microbiol. (1993). 47, 263-290.

[65] Lundgren, D.G. & Silver, M.. Ore leaching by bacteria. Ann. Rev. Microbiol., 1980, N° 34, p. 263-283.


[66] Macy, J. M., Santini, J. M., Pauling, B. V., O'Neill, A. H., & SLY, L. I.. Two new arsenate/sulfate-reducing bacteria: mechanisms of arsenate reduction. Arch.Microbiol. 2000, 173, 49-57.

[67] Maraval, S. (1994). Etude comparative de divers liants hydrauliques et de la vitrification, cas des cendres d'incinération d'ordures ménagères 325 p. INSA de Lyon. thèse.

[68] Quevauviller P., Rauret G., Lopez-Sanchez J.F., Rubio R., Ure A.M., Muntau H. Certification of trace metal extractable contents in a sediment reference material (CRM 601) following a three step sequential extraction procedure, 1998.

[69] Stolz, J. F. & Oremland, R. S.. Bacterial respiration of arsenic and selenium. (1999). FEMS Microbiol.Rev. 23, 615-627.

[70] Toniazzo, V.. Approche des mécanismes d’oxydation de la pyrite par Thiobacillus ferroxidans grâce à la modélisation morpho-chimique de la surface minérale : Rôle fondamental des phases superficielles oxydées. Thèse, 1998, Université Henry Poincaré, Nancy 1. 195 p.

Pour en savoir plus

Larpent, J. & Larpent-Gourgaud, M.. Momento technique de microbiologie. Lavoisier, Collection tech & Doc, 1990, 417 P..

Pelmont, J.. Bactéries et Environnement, Adaptations Physiologiques. Presses Universitaires de Grenoble, 1993, 899 p..


Stabilisation physico-chimique (technique n°7)

Littérature citée

[14] Cornu S., Clozel B. (2000) : Extractions séquentielles et spéciation des éléments trace métalliques dans les sols naturels : analyse critique. Accepté à Etude et Gestion des Sols.


[71] Pourbaix M. Atlas d'équilibres électrochimiques à 25°C. Paris : Gauthier Villars, 1963, 644 p.

Pour en savoir plus

Akhter H., Butler LG., Branz S., Cartledge FK., Immobilisation of arsenic, cadmium, chromium and lead containing soils by using cement or pozzolanic fixing agents, J. Hazard. Mater, 1990, 24 (2-3), 145-155

Baldwin CE., Sogue A., Treating wastes, preparing construction materials and stabilizing, US Patent, WO 9942231

Boisson J., Mench M., Vangronsveld J., Ruttens A., Immobilization of trace metals and arsenic by different soil additives : evolution by means of chemical extractions, Commun. Soil Sci, Plant Anal., 1999, 30 (3 & 4), 365-387

Brodersen K., Hjelman O., Moztensen S., Cement conditioning of waste materials and polluted soil using the GEODUR process, ASTM Spec. Tech. Publ., 1992, STP 1123, 2nd Vol., 320-37

Brown S., Chaney R., Angle JS., Subsurface liming and metal movement in soils amended with lime - stabilized biosolids, J. Environ. Qual., 1997, 26(3), 724-732

Chang F., Broadbent FE., Effect of nitrification on movement of trace metals in soil columns, J. Environ. Qual., 1980, 9(4), 587-92

Ford RG., Scheinost AC., Scheckel KG., Sparks DL., The link between clay mineral weathering and the stabilization of nickel surface precipitates, Environ. Sci. Technol., 1999, 33(18), 3140-3144

Ganev S., Chuldzhiyan H., Petrov P., Ilkov G., Chemical amelioration of soils polluted with copper and acid sediments, Pochvozn - Agrokhim. Raslit Zasht, 1985, 20-6), 3-18, (en Bulgare, résumé en anglais)

Haider, Konrad, From dead organic residue to humus, . Plant Nutr. Soil. Sci., 1999, 162(4), 363-371

Jones, Bradford H., Process and apparatus for fixing, encapsulating, stabiling and detoxifying heavy metals and the like in metal containing suldges, soils, ash and similar materials, Patent EP 234087

Kinuthia JM., Wild S., Jones GI., Effects of monovalent and divalent metal sulfates on consistency and compaction of lime - stabilized kaolinite, Appl. Clay. Sci., 1999, 14(1-3), 27-45

Lin Z., Cumet B., Qvarfort V., Herbert R., The chemical and mineralogical behavior of Pb in shooting range soils from central Sweden, Environ. Pollut., 1995, 89(3), 303-9

Luo YM., Christie P., Bioavailability of copper and zinc in soils treated with alkaline stabilized sewage sludges, J. Environ. Qual., 1998, 27(2), 335-42

Mench M., Vangronsveld J., Didier V., Clijsters H., Evaluation of metal mobility, plant availability and immobilization by chemical agents in a limed - silty soil, Envion. Pollut., 1994, 86(3), 279-86


Ramos L., Hernandez LM., Gonzalez MJ., Sequential fradionation of copper, lead, cadmium and zinc in soils from or near Donana National Park, J. Environ. Qual., 1994, 23(1), 50-7

Somers WR., Goldstein GL., Bankston W., Burk R., Use of stabilized bayer spent bauxite as engincered landfill cover, Ind. Wasters Tech. Conf. : Multimedia Pollut. Control Prev., 1995, 8119-30

Sullivan J., King L., Reith CC., Versatile process recycles contaminated soil and other solid waste into construction material for commercial application, Proc. Annu. Meet., Air Waste Manage. Assoc., 1998, 91st, TP 5402/1, TP 5402/5

Tasaka I., Egawa H., Yuneda O., Consolidation materials for backfilling and consolidating soil, J.P. Patent 10182212 (résumé anglais)

Thiry M., Folkert Van Oort, Les phases minérales majeures et mineures d'une friche industrielle de métallurgie des métaux non ferreux : état d'altération, évolution géochimique et devenir des métaux polluants du site de Mortagne du Nord, Spéciation des métaux dans le sol, Ed. Association ECRIN, 1999, 108-133

Tiller KG., Gerth J., Bruemmer G., The sorption of cadnium, zinc and nickel by soil clay fractions : procedures for partition of bound forms and their interpretation, Geoderma, 1984, 34(1), 1-16

Trepanowski JJ., Brayack DD., Pike JA., Investigation of stabilizing arsenic-bearing soils and wastes using cement casting and clay pelletizing / sintering technologies, EPA, Int. Conf. New. Front. Hazard. Waste Manage., 3rd, 1989, 166-75

Vipulanandan C., Wang S., Solidification / stabilization of hexavalent chromium contaminated soil, Geotech. Spec. Publ., 1997, 71, 362-373

Wagh AS., Jeong SY., Singh D., Strain R., Stabilization of contaminated soil and waster water with chemically bonded phosphate ceramics, WM'97 Proc., 1997, 1854-1859, Publisher : WM Symposia Inc., Tucson, Aziz

Wenger K., Hari T., Gupta SK., Krebs R., Possible approaches for in situ restoration of soils contaminated by zinc, Adv. Geo. Ecol., 1998, 31(1), 745-753


Bio-immobilisation (technique n°8)

Littérature citée

[72] Bopp L.H. & Ehrlich, H.L.. Chromate Resistance and Reduction in Pseudomonas fluorescens Strain LB300. Archives of Microbiology, 1988, Vol. 150, p. 426-431.

[73] Cervantes, C.. Bacterial Interactions with Chromate. Antonie van Leewenhoek, 1991, Vol. 59, p. 229-233.

[74] Cervantes C. & Silver, S.. Plasmid Chromate Resistance and Chromate Reduction. Plasmid, 1992, Vol. 27, p. 65-71.

[75] Cervantes, C., Campos-Garcia, J., Devars, S., Gutierrez-Corona, F., Loza-Tavera, H., Torres-Guzman, J. C., & Moreno-Sanchez, R.. Interactions of chromium with microorganisms and plants. FEMS Microbiol. Rev., 2001, vol. 25, n°3, pp 335-347.

[76] Cifuentes F.R., Lindeman, W.C. & Barton, L.L.. Chromium Sorption and Reduction in Soil with Implication to Bioremediation. Soil Science, 1996, Vol. 51, n°4, p.233-241.

[77] Chirwa, E. M. N. & Wang, Y.T.. Simultaneous chromium (VI) reduction and phenol degradation in an anaerobic consortium of bacteria. Water Research, 2000, vol. 34, n°8, pp 2376-2384.

[78] Das, S. & Chandra, A. L.. Chromate reduction in Streptomyces. Experientia, 1990, vol. 46, pp 731-733.

[79] Desjardin, V., Bayard, R., Huck, N., Manceau, A., & Gourdon, R.. Effect of microbial activity on the mobility of chromium in soils. Waste Management, 2002a, vol. 22, pp 195-200.

[80] Desjardin, V., Bayard, R., Lejeune, P., & Gourdon, R.. Utilisation of supernatants of pure culture of Streptomyces thermocarbonxydus to reduce chromium toxicity & mobility in contaminated soils. Water Air & Soil Pollution, 2002b. Accepté.

[81] Desjardin, V.. Réduction du chrome (VI) par la souche Streptomyces thermocarboxydus NH50 isolée à partir d’un sol pollué. (2002), Thèse. INSA de Lyon. 246 p. 02-ISAL-0030.

[82] Dhakephalkar, P. K., Bhide, J. V., & Paknikar, K. M.. Plasmid mediated chromate resistance and reduction in Pseumonas mendocina MCM B-180. Biotechnology Letters, 1996, vol. 18, n°10, pp 1119-1122.

[83] Garbisu, C., Alkorta, I., Llama, M. J., & Serra, J. L. Aerobic chromate reduction by Bacillus subtilis. Biodegradation., 1998, vol. 9, n°2, pp 133-141.

[84] Gourdon, R. ; Huck, N. ; Lauriat, A. & Bayard, R. Effect of Microbial Activity on the Mobility of Chromium in Soils. International Conference on Waste Stabilization and Environment April 13-16 1999, Villeurbanne, France.(1999).

[85] Horitsu, H., Futo, S., Miyazawa, Y., Ogai, S., & Kawai, K. Enzymatic reduction of hexavalent chromium by hexavalent chromium tolerant Pseudomonas ambigua G-1. Agric. Biol. Chem., 1987, vol. 51, 9, pp 2417 -2420.

[86] Losi, M. E., Amrhein, C., & Frankenberger JR, W. T.. Factors affecting chemical and biological reduction of hexavalent chromium in soil. Environmental Toxicology and Chemistry, 1994, vol. 13, n°11, pp 1727-1735.

[87] Lovley, D. R. & Phillips, E. J.. Reduction of chromate by Desulfovibrio vulgaris and its c3 cytochrome. Appl. Environ. Microbiol, 1994, vol. 60, n°2, pp 726-728.


[88] Romanenko, V. I. & Koren'kov, V. W., A pure culture of bacteria utilizing chromates and bichromates as hydrogen acceptors in growth under anaerobic conditions. Mikrobiologiya, 1977, vol. 46, pp 414-417.

[89] Turick C.E., Appel, W.A. & Armiol, N.S.. Isolation of Hexavalent Chromium-Reducing Anaerobes from Hexavalent-Chromium-Contaminated & Noncontaminated Enviroments. Applied Microbial Biotechnology, 1996, Vol. 44, p. 683-688.

[90] Turick C.E., Graves, C. & Appel, W.A.. Bioremediation Potential of Cr(VI)-Contaminated Soil using Indigenous Microorganisms. Bioremediation Journal, 1998, Vol. n°1, p. 1-6.

[91] Wang, Y. T. & Shen, H,. Bacterial reduction of hexavalent chromium. Journal of Industrial Microbiology, 1995, vol. 14, pp 159-163.

Pour en savoir plus Larpent, J. & Larpent-Gourgaud, M.. Momento technique de microbiologie. Lavoisier, Collection tech & Doc, 1990, 417 P..

Pelmont, J.. Bactéries et Environnement, Adaptations Physiologiques. Presses Universitaires de Grenoble, 1993, 899 p..


Phytostabilisation (technique n°9)

Littérature citée [67] Maraval, S. (1994). Etude comparative de divers liants hydrauliques et de la vitrification, cas des cendres d'incinération d'ordures ménagères 325 p. INSA de Lyon. thèse.

[92] Boisson, J., Ruttens, A., Mench, M. et Vangronsveld, J., 1999, Evaluation of hydroxyapatite as a metal immobilizing soil additive for the remediation of polluted soils. Part 1. Influence of hydroxyapatite on metal exchangeability in soil, plant growth and plant metal accumulation, Environ. Pollution, 104(2): 225-233.

[93] Chaney, R.L., Malik, M., Li, Y.M., Brown, S.L., Brewer, E.P., Angle, J.S. et Baker, A.J., 1997, Phytoremediation of soil metals, Current Opinion in Biotechnology, 8(3): 279-284

[94] Grcman, H., Velikonja-Bolta, S., Vodnik, D., Kos, B. et Lestan, D., 2001, EDTA enhanced heavy metal phytoextraction: metal accumulation, leaching and toxicity, Plant and Soil, 235: 105-114

[95] Mench, M., J. Vangronsveld, V. Didier, et H. Clijsters. 1994. Evaluation of metal mobility, plant availability and immobilization by chemical agents in a limed-silty soil. Environmental Pollution 86:279-286.

[96] Morel, J.L. 1996. Bioavailability of trace elements to terrestrial plants. In Soil Ecotoxicology, edited by J. Taradellas, G. Bitton and D. Rossel. Boca Raton, Fl: Lewis Publishers.

[97] Susarla, S., Medina, V.F. et McCutcheon, S.C., 2002, Phytoremediation: An ecological solution to organic chemical contamination, Ecological Engineering, 18(5): 647-658

[98] Vangronsveld, J., F. Van Assche, and H. Clijsters. 1995. Reclamation of a bare industrial area contaminated by non-ferrous metals : in situ metal immobilization and revegetation. Environmental Pollution 87:51-59.

[99] Vangronsveld, J., J. Sterckx, F. Van Assche, and H. Clijsters. 1995. Rehabilitation studies on an old non-ferrous waste dumping ground : effects of revegetation and metal immobilization by beringite. Journal of Geochemical Exploration 52:221-229.

[100] Ye, Z.H., Wong, J.W.C., Wong, M.H., Lan, C.Y. et Baker, A.J.M., 1999, Lime and pig manure as ameliorants for revegetating lead/zinc mine tailings : a greenhouse study, Bioresource Technology, 69: 35-43


Biodégradation (technique n°10)

Littérature citée

[4] Yaws CL (1999). Chemical Properties Handbook : physical, thermodynamic, environmental, transport, safety, and health related properties for organic and inorganic chemicals. McGraw-Hill (ed), New York.

[101] EPA (a). 542-R-00-008 (2000). Engineered approaches to « in situ » bioremediation of chlorinated solvents : fundamentals and field applications. US EPA: Office of solid waste and emergency response.

[102] Fetzner S. (1998). Bacterial dehalogenation. Appl. Microbiol. Biotechnol.,50 , 633-657.

[103] Semprini L (1997). Strategies for the aerobic co-metabolism of chlorinated solvents. Curr.Opin.Biotechnol. 8, 296-308.(ref 43)

Pour en savoir plus

Davis-Hoover WJ, Bryndzia LT, Roullier MH, Murdoch LC, Kemper M, Cluxton P, AlAbed S, Slack WW, Vesper SJ (1999). In situ Bioremediation utilizing horizontal Lasagna TM. In Engineered approaches for in situ Bioremediation of chlorinated solvent contamination., Eds Leeson A. and Alleman B., San Diego, California, Colombus, Batelle Press, pp263-269.

EPA (b). 542-R-00-004 (2000). Treatment technology for Site Cleanup. Annual status report, Tenth Edition. (http://www.epa.gov/tio).

EPA (c). 542-R-01-008 (2001). Abstract of remediation case studies, vol 5. (http://www.epa.gov/tio/pub).

Gribble GW (1994). The natural production of chlorinated compounds. Environ. Sci. Technol., 28, 7, 310A-317A.

Harkness MR (1999). Use of bioaugmentation to stimulate complete reductive dechlorination of trichloroethene in Dover soil columns. Environ. Sc. Technol. 33, 1100-1109.

Hartman S, DeBont J (1992). Aerobic Vinyl chloride metabolism in Mycobacterium aurum L1. Appl. Environ. Microbiol. 58, 1220-1226.

Hazen TC, Lombard KH, Looney BB, Enzien MV, Dougherty JM, Fliersmans CB, Wear J, Eddy-Dilek CA (1994). Summary of in situ bioremediation (methane biostimulation) via horizontal wells at the Savannah river site integrated demonstration project. In "In situ" remediation: scientific basis for current and future technologies. Richland, Washington: Batelle Press, pp137-150.

Hinchee R.E., Ong S.K. (1992). A rapid in situ respiration test for measuring aerobic biodegradation rates of hydrocarbons in soil. J. Air Waste Manage. Assoc. 42 (10), 1305-1312.

Semprini L (2001). Editorial. Biodegradation. 12, 79-80

Sentissi S, Ropars M (2000). Etude de la biodégradation des hydrocarbures chlorés en conditions aérobies et anaérobies. Rapport IFP 54352.

Wilson JT et Wilson BH (1985). Biotransformation of trichloroethylene in soil. Appl. Environ. Microbiol, 29, 242-243


Oxydation chimique in situ (technique n°11)

ITRC (2005) - Technical and regulatory guidance for in situ chemical oxidation of contaminated soil and groundwater, Second edition. 71p. Disponible sur : http://www.itrcweb.org/Documents/ISCO-2.pdf.

SERDP (2004) - Annual report, In situ chemical oxidation initiative. 10p. Disponible sur : http://www.serdp.org.

Touzé S., Ignatiadis I., Saada A., Gaboriau H. (2005) - Etat de l’art de la technologie de l’oxydation in situ. BRGM/RP-54096-FR

Cline S.R., Giaquinto J.M., McCracken M.K., Denton D.L. Starr R.C. (1999) - Laboratory evaluation of in situ chemical oxidation for groundwater remediation, test area north, operable unit 1-07B, Idaho National engineering and environmental laboratory. Oak ridge national laboratory. ORNL/TM-13711/V1

EPA (2005) - In-Situ DUOX™ Chemical Oxidation Technology to Treat Chlorinated Organics at the Roosevelt Mills Site, Vernon, CT Site Characterization and Treatability Study Report. Disponible sur : http://www.epa.gov/ORD/NRMRL/pubs/540r05008/540r05008.pdf

Dijkshioom P. (2003) - In situ chemical oxidation of chlorinated solvents with potassium permanganate on a site in Belgium. Consoil 2003.

EPA (1998) - Field Applications of In situ Remediation technologies. EPA-542-R-98- 008. Disponible sur : http://www.clu-in.org/download/remed/chemox.pdf.

EPA (2004) - DNAPL remediation: selected projects approaching regulatory closure.

EPA 542-R-04-016, 2004. Disponible sur : http://clu-in.org/download/remed/542r04016.pdf.

Heron T. (2003) - Permanganate oxidation of PCE in Moraine Clay at a dry Cleaning Facility. Part 1. Choice of oxidant, laboratory testing & design considerations. Consoil 2003. In Situ Technieken BV. Disponible sur : http://www.insitu.nl/index.php.

INRS (1992) - Peroxyde d'hydrogène et solutions aqueuses. Fiche toxicologique N° 123. Disponible sur : http://www.inrs.fr/.

INRS (1997) - Ozone. Fiche toxicologique N° 43. Disponi ble sur : http://www.inrs.fr/.

ITRC (2001) - Technical and regulatory guidance for in situ chemical oxidation of contaminated soil and groundwater, First edition. 25p. Disponible sur : http://www.itrcweb.org/Documents/ISCO-1.pdf.

ITRC (2005) - Technical and regulatory guidance for in situ chemical oxidation of contaminated soil and groundwater, Second edition. 71p. Disponible sur : http://www.itrcweb.org/Documents/ISCO-2.pdf.

Larsen (2004) - Injection of Fentons reagent in situ; case studies. Renare Mark. Disponible sur : http://www.renaremark.se/filarkiv/hm2004/lars_larsen.pdf.

Pancras T.A. (2005) - Fenton oxidation of a benzene contamination in alkaline soil. Consoil 2005.

Plaisier W. (2003) - Performing in situ chemical oxidation with fenton’s reagent at a former gas work in Rotterdam. Consoil 2003. QDS. Disponible sur : http://www.qdsltd.com

SCRD - State Coalition for Remediation of Drycleaners( SCRD). Disponible sur : http://www.drycleancoalition.org/

SERDP (2004) - Annual report, In situ chemical oxidation initiative. 10 p. Disponible sur : http://www.serdp.org.


Vik E.A., Bardos P. (2002) - Remediation of contaminated land technology implementation in Europe, CLARINET p. 70. Disponible sur : http://www.clarinet.at/library/WG7_Final_Report.pdf

Volkering F. (2005) - Monitoring in situ permanganate oxidation of chlorinated using stable isotope analysis. Consoil 2005.

Agence de l’Environnement et de la Maîtrise de l’Energie20, avenue du Grésillé - BP 90406

49004 Angers Cedex 01www.ademe.fr

L’ADEME en bref

L'Agence de l'Environnement et de la Maîtrise de l'Energie (ADEME) est un établissement public sous la tutelle conjointe duministère de l'Ecologie, de l'Energie, du Développement durable et de la Mer et du ministère de l’Enseignement supérieur et dela Recherche. Elle participe à la mise en oeuvre des politiques publiques dans les domaines de l'environnement, de l'énergie etdu développement durable.

Afin de leur permettre de progresser dans leur démarche environnementale, l'agence met à disposition des entreprises, descollectivités locales, des pouvoirs publics et du grand public, ses capacités d'expertise et de conseil. Elle aide en outre aufinancement de projets, de la recherche à la mise en œuvre et ce, dans les domaines suivants : la gestion des déchets, lapréservation des sols, l'efficacité énergétique et les énergies renouvelables, la qualité de l'air et la lutte contre le bruit.

Liste des auteursCe guide a été élaboré sous la direction de :

Nadine DUESO et de Frédérique CADIERE (ADEME - Département Sites et Sols Pollués)

avec la collaboration de nombreux participants :Gérard ANTONINI, PROCEDIS - Daniel BALLERINI, IFP - Fabienne BATTAGLIA-BRUNET, BRGMRémy BAYARD, INSA de Lyon - Belkacem BENADDA, INSA de Lyon - Denis BLANCHET, IFP

Ottmane BOUDOUCH, INSA de Lyon - Jean CARRE, Université Claude Bernard Lyon 1Blandine CLOZEL, BRGM - Pierre CONIL, BRGM - Stéfan COLOMBANO, BRGM

Camille DUTHEIL, INSA de Lyon - Hervé GABORIAU, BRGM - Rémy GOURDON, INSA de LyonFrank HAESELER, IFP - Mourad HAZI, Université de Technologie de Compiègne - Daniel HUBE, BRGM

Ioannis IGNIATIADIS, BRGM - Jean-Marie LETOFFE, Université Claude Bernard Lyon 1Marcel ROPARS, IFP - Catherine SCHMITT, ENSAIA / INRA

Christophe SCHWARTZ, ENSAIA / INRA - Jacques THIRY, COGEMA - Solène TOUZE, BRGM

Emmanuel VERNUS, INSAVALOR - Division POLDEN

Traitabilité des sols pollués - · PDF fileRéférences...

Documents

Transcript of Traitabilité des sols pollués - · PDF fileRéférences...