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Phytoremediation on the Heavy Metal Contaminated Soil by Hyperaccumulators in the Greenhouse
Park, Sang-Hean;Choi, Sang-Il;Park, Jong-Bu;Han, Ha-Kyu;Bae, Sei-Dal;Sung, Il-Jong;Park, Eung-Ryeol;
Department of Environmental Engineering, Kwangwoon University;Department of Environmental Engineering, Kwangwoon University;Research Institute of Technology, Hanwha E&C Corp.;Korea Environment Corporation;Department of Environmental Engineering, Kwangwoon University;Department of Environmental Engineering, Kwangwoon University;Department of Environmental Engineering, Kwangwoon University;
식물경작장에서의 중금속 고축적종 식물을 이용한 중금속 오염토의 정화 연구
박상헌;최상일;박종부;한하규;배세달;성일종;박응렬;
광운대학교 환경공학과;광운대학교 환경공학과;(주)한화건설 기술연구소;한국환경공단;광운대학교 환경공학과;광운대학교 환경공학과;광운대학교 환경공학과;

Abstract

This study was performed to evaluate the remediation efficiency by Helianthus annuus, Brassica juncea and Brassica campestris on the soil contaminated with nickel, zinc and lead, respectively. The growth rates fell down under 60% in the condition of over 700 mg/kg of zinc for Brassica campestris, 300 mg/kg of lead for Helianthus annuus, and 150 mg/kg of nickel for Brassica juncea on the basis of heavy metal concentration in the soil, because of its toxicity. Also, the hyperaccumulators showed the maximum heavy metal contents in their biomass after 90 days of cultivation. The accumulated heavy metal content per kilogram of hyperaccumulator was 0.65 mg of nickel in Brassica juncea, 0.14 mg of zinc in Brassica campestris, and 0.06 mg of lead in Helianthus annuus, respectively. Additionally, 73.2% of nickel accumulated in Brassica juncea and 95.1% of zinc accumulated in Brassica campestris were concentrated in the upper site of crop like stem and leaves. However, in the case of Helianthus annuus, 83.7% of lead was accumulated in the root.

Keywords: Phytoremediation;Heavy metal;Toxicity;Hyperaccumulator;

References

1. 강정우, 2002, Phosphate를 이용한 군부대 중금속 오염토양의 안정화, 광운대학교 석사학위 논문, 38-42.
2. 김정규, 임수길, 이상환, 이창호, 정창윤, 1999, 휴.폐광지역 오염토양의 Phytoremediation을 위한 식물자원 검색, 환국환경농학회지, 18(1), 28-34.
3. 김현희, 2003, 포사격장의 중금속 오염도 조사 및 피 (Echinochloa crusgalli var. Frumentacea)와 해바라기 (Helianthus annuus)를 이용한 납의 Phytoextraction에 관한 연구, 지하수토양환경, 8, 30-45.
4. 동화기술, 2009, 수질오염.폐기물.토양오염 공정시험기준.
5. Baker, A.J.M. and Brooks, R.R., 1989, Terrestrial higher plants which hyperaccumulate metallic elements - A review of their distribution, ecology and phytochemistry, Biorecovery, 1, 81-126.
6. Ebbs, S.D., Lasat, M.M., Brady, D.J., Cornish, J., Gorden, R., and Kochian, L.V., 1997, Phytoextraction of cadmium and zinc from a contaminated soil, J. Environ. Qual., 26, 1424-1430.
7. Ensley, B.D., 1991, Biochemical Diversity in Trichloroethylene Metabolism, Annu. Rev. Microbiol., 4, 283-299.
8. Koopermans, G.F.P.F.A.M., Song, J., Temminghoff, E.J.M., and Japenga, J., 2007, Predicting the phytoextraction duration to remediate heavy metal contaminated soils, Water Air Soil Pollut., 181, 355-371.
9. Kumar, P.B.A.N., Dushenkov, V., Motto, H., and Raskin,, I., 1997, Phytoextraction: The use of plants to remove heavy metals from soils, Environmental Science and Technology, 29(5), 1232-1238.
10. Terry, N., Carlson, C., and Raab, T.K., 1992, Rates of Se volatilization among crop species, J. Environ. quality, 21, 341-344.
11. Wang, W., 1991, Literature review on higher plants for toxicity testing, Water Air Soil Poll., 59, 381-410.

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