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Desorption of Heavy Petroleum Oils and Heavy Metals from Soils by Flushing Agents
Yun, Sung Mi;Kim, Gil Ran;Lim, Hee Jun;Kim, Han S.;
Department of Environmental Engineering, Konkuk University;Department of Environmental Engineering, Konkuk University;Department of Environmental Engineering, Konkuk University;Department of Environmental Engineering, Konkuk University;
세정제에 의한 복합오염토양으로부터의 중질유 및 중금속 탈착 특성
윤성미;김길란;임희준;김한승;
건국대학교 환경공학과;건국대학교 환경공학과;건국대학교 환경공학과;건국대학교 환경공학과;

References

1. Ahn, C.K., Woo, S.H., and Park, J.M., 2008, Process evaluation of soil washing including surfactant recovery by mathematical simulation, J. Soil Groundw. Environ., 13, 32-42.
2. Akpoveta, V.O., Osakwe, S., Egharevba, F., Medjor, W.O., Asia, I.O., and Ize-Iyamu, O.K., 2012, Surfactant enhanced soil washing technique and its kinetics on the remediation of crude oil contaminated soil, Pac. J. Sci. Technol., 13, 443-456.
3. Arias, M., Perez-Novo, C., Lopez, E., and Soto, B., 2006, Competitive adsorption and desorption of copper and zinc in acid soils, Geoderma, 133, 151-159.
4. Camargo, I.M.C., Hiromoto, G., and Flues, M., 2007, Heavy metal partition in acid soils contaminated by coal power plant, J. Braz. Chem. Soc., 18, 831-837.
5. Chen, Z., Xing, B., and Mcgill, W.B., 1999, A unified sorption variable for environmental applications of the Freundlich isotherm, J. Environ. Qual., 28, 1422-1428.
6. Coles, C.A. and Yong, R.N., 2006, Use of equilibrium and initial metal concentrations in determining Freundlich isotherms for soils and sediments, Eng. Geol., 85, 19-25.
7. Dahlmann, G., 2003, Characteristic Features of Different oil Types in Oil Spill Identification, Bundesamt fur Seeschifffahrt und Hydrographie, Hamburg and Rostock, Germany, 10-27 p.
8. Dermont, G., Bergeron, M., Mercier, G., and Richer-Lafleche, M., 2007, Soil washing for metal removal: a review of physical/ chemical technologies and field applications, J. Hazard. Mater., 152, 1-31.
9. Diatta, J.B., Kocialkowski, W.Z., and Grzebisz, W., 2003, Lead and zinc partition coefficients of selected soils evaluated by Langmuir, Freundlich, and linear isotherms, Commun. Soil Sci. Plant Anal., 34, 2419-2439.
10. DOEIP, 1995, Railway Land, Department of the Environment Industry Profile, Ruislip, UK, 11-12 p.
11. Fifi, U., Winiarski, T., and Emmanuel, E., 2013, Assessing the mobility of lead, copper and cadmium in a calcareous soil of Port-au-Prince, Haiti, Int. J. Environ. Res. Public Health, 10, 5830-5843.
12. Finzgar, N. and Lestan, D., 2008, The two-phase leaching of Pb, Zn and Cd contaminated soil using EDTA and electrochemical treatment of the washing solution, Chemosphere, 73, 1484-1491.
13. Frysinger, G.S., Gaines, R.B., Xu, L., and Reddy, C.M., 2003, Resolving the unresolved complex mixture in petroleum-contaminated sediments, Environ. Sci. Technol., 37, 1653-1662.
14. Jeong, T.H., 2013, Stabilization of heavy metal in abandoned metal mine soil by soluble phosphate and steel slag, Master's Thesis, Konkuk University, Seoul, Korea, p. 21-23.
15. Jian-Hua, M., Chun-jie, C., Jian, L., and Bo, S., 2009, Heavy metal pollution in soils on railroad side of Zhengzhou-putian section of Longxi-Haizhou railroad, China, Pedosphere, 19, 121-128.
16. Kim, J.D. and Namkoong, W., 1992, Comparison of leaching tests for solidified hazardous wastes, J. Korea Soc. Waste Manag., 9, 261-270.
17. Lee, L.S., Zhai, X., and Lee, J., 2007, INDOT guidance document for in-situ soil flushing, JTRP Technical Reports, Purdue University, West Lafayette, Indiana, p. 8-16.
18. Lee, Y.H. and Oa, S.W., 2012, Desorption kinetics and removal characteristics of Pb-contaminated soil by the soil washing method: mixing ratios and particle sizes, Environ. Eng. Res., 17, 145-150.
19. Mackay, A.A., Chin, Y., Macfarlane, J.K., and Gschwend, P.M., 1996, Laboratory assessment of BTEX soil flushing, Environ. Sci. Technol., 30, 3223-3231.
20. Mao, M. and Ren, L., 2004, Simulating nonequilibrium transport of atrazine through saturated soil, Ground water, 42, 500-508.
21. Mulligan, C.N., Yong, R.N., and Gibbs, B.F., 2001, Surfactantenhanced remediation of contaminated soil: a review, Eng. Geol., 60, 371-380.
22. NFESC, 1998, Application guide for thermal desorption systems, Technical Report, Naval Facilities Engineering Services Center, Port Hueneme, California, p. B.4.4-C.2.3.
23. Oa, S.W. and Lee, T.G., 2009, Investigation of soil pollution status for railroad depot, J. Korean Soc. Railw., 12, 788-792.
24. Oh, S.S., Hyun, H.N., and Moon, D.K., 2000, Adsorption coefficients of eight pesticides for citrus orchard soil with different soil organic matter, Korean J. Environ. Agric., 19, 6-12.
25. Ousmanova, D. and Parker, W., 2007, Fungal generation of organic acids for removal of lead from contaminated soil, Water Air Soil Pollut., 179, 365-380.
26. Richmond, S.A., Lindstrom, J.E., and Braddock, J.F., 2001, Effects of chitin on microbial emulsification, mineralization potential, and toxicity of bunker C fuel oil, Mar. Pollut. Bull., 42, 773-779.
27. Santana-Casiano, J.M. and Gonzalez-Davila, M., 1992, Characterization of the sorption and desorption of lindane to chitin in seawater using reversible and resistant components, Environ. Sci. Technol., 26, 90-95.
28. Scarlett, A., Galloway, T.S., and Rowland, S.J., 2007, Chronic toxicity of unresolved complex mixtures (UCM) of hydrocarbons in marine sediments, J. Soils Sediments, 7, 200-206.
29. Shariff, R.M. and Esmail, L.S., 2012, Adsorption-desorption for some heavy metals in the presence of surfactant on six agricultural soils, Int. J. Res. Rev. Appl. Sci., 12, 536-552.
30. Speight, J.G. and Arjoon, K., 2012, Bioremediation of petroleum and petroleum products, Wiley & Sons and Scrivener Publishing, Hoboken and Salem, USA, 97 p.
31. Strawn, D.G. and Sparks, D.L., 2000, Effects of Soil organic matter on the kinetics and mechanisms of Pb(II) sorption and desorption in soil, Soil Sci. Soc. Am. J., 64, 144-156.
32. Subramaniam, K., Stepp, C., Pignatello, J.J., Smets, B., and Grasso, D., 2004, Enhancement of polynuclear aromatic hydro carbon desorption by complexing agents in weathered soil, Environ. Eng. Sci., 21, 515-523.
33. U.S. EPA, 1996, Total Recoverable Petroleum Hydrocarbons by Infrared Spectrophotometry, EPA Method 8440, U.S. Environmental Protection Agency.
34. U.S. EPA, 1997, Recent Developments for In Situ Treatment of Metal Contaminated Soil, EPA Method 68-W5-0055, U.S. Environmental Protection Agency, Washington D.C., USA, 2 p.
35. U.S. EPA, 2006, In-situ treatment technologies for contaminated soil, EPA Method 542-F-06-013, Engineering Forum Issue Paper, Solid Waste and Emergency Response, p. 12-13.
36. Violante, A., Cozzolino, V., Perelomov, L., Caporale, A.G., and Pigna, M., 2010, Mobility and bioavailability of heavy metals and metalloids in soil environments, J. Soil. Sci. Plant Nutr., 10, 268-292.
37. Wilkomirski, B., Halina, G., Wojcikowska, B.S., Staszewski, T., and Malawska, M., 2012, Railway tracks-habitat conditions, contamination, floristic settlement-a review, Environ. Nat. Resour. Res., 2, 86-95.
38. Yaacob, W.Z.W., Samsudin, A.R., and Kong, T.B., 2008, The sorption distribution coefficient of lead and copper on the selected soil samples from Selangor, Geol. Soc. Malays. Bull., 54, 21-25.

This Article

2014; 19(3): 94-103

Published on Jun 30, 2014
10.7857/JSGE.2014.19.3.094
Received on Mar 27, 2014
Revised on Apr 17, 2014
Accepted on Apr 20, 2014

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