Browse > Article

Stabilization of As (arsenic(V) or roxarsone) Contaminated Soils using Zerovalent Iron and Basic Oxygen Furnace Slag  

Lim, Jung-Eun (Department of Biological Environment, Kangwon National University)
Kim, Kwon-Rae (Division of Environmental Science and Ecological Engineering, Korea University)
Lee, Sang-Soo (Department of Biological Environment, Kangwon National University)
Kwon, Oh-Kyung (National Academy of Agricultural Science)
Yang, Jae-E (Department of Biological Environment, Kangwon National University)
Ok, Yong-Sik (Department of Biological Environment, Kangwon National University)
Publication Information
Journal of Korean Society of Environmental Engineers / v.32, no.6, 2010 , pp. 631-638 More about this Journal
Abstract
The objective of this study was to evaluate the efficiency of zerovalent iron and basic oxygen furnace slag on arsenic stabilization in soils. For this, arsenic (V) contaminated soil and roxarsone contaminated soil were incubated after incorporation with zerovalent iron (ZVI) or basic oxygen furnace slage (BOFS) at four different levels (0%, 1%, 3%, and 5%) for 30 days and then the residual concentrations of arsenic were analysed following extraction with aqua reqia, 1N HCl and 0.01 M $CaCl_2$. The total concentration of arsenic was 2,285 mg/kg in the As(V) contaminated soil and 6.5 mg/kg in the roxarsone contaminated soil. 1 N HCl extractable arsenic concentration in the As(V) contaminated soil was initially 1,351 mg/kg and this was significantly declined by 713~1,034 mg/kg following incubation with ZVI while BOFS treatment showed no effect on the stabilization of inorganic arsenate except 5% treatment which showed around 100 mg/kg reduction in 1N HCl extractable arsenic. Similarly, in the roxarsone contaminated soil 1N HCl extractable concentration of arsenic was reduced from 3.13 mg/kg to 0.69 mg/kg with ZVI treatment increased from 1% to 5% while BOFS treatment did not lead to any statistically significant reduction. Available (0.01M $CaCl_2$ extractable) arsenic was initially 0.85 mg/kg in the As(V) contaminated soil and this declined by 0.79 mg/kg following incorporation with 5% ZVI, which accounted for more than 90% of the available As in the control. When As(V)-contaminated soil was treated with BOFS, the available arsenic was increased due to competing effect of the phosphate originated from BOFS with arsenate for the adsorption sites. For the roxarsone contaminated soil, the greater the treatment of ZVI or BOFS, the lower the available arsenic concentration although it was still higher than that of the control.
Keywords
Stabilization; Zerovalent iron; Basic oxygen furnace slag; Arsenic; soil quality;
Citations & Related Records
Times Cited By KSCI : 6  (Citation Analysis)
연도 인용수 순위
1 Rau, I., Gonzalo, A., and Valiente, M., "Arsenic(V) adsorption by immobilized iron mediation. Modeling of the adsorption process and influence of interfering anions," Reac. Functional Polymers, 54(1-3), 85-94(2003).   DOI
2 Cortinas, I., Field, J. A., Kopplin, M., Garbarino, J. R., Gandolfi, A. J., and Sierra-alvarez, R., "Anaerobic Biotransformation of Roxarsone and Related N-Substituted Phenylarsonic Acids," Environ. Sci. Technol., 40(9), 2951-2957(2006).   DOI   ScienceOn
3 Roerdink, A. R., and Aldstadt, J. H., "Sensitive method for the determination of roxarsone using solid-phase microextraction with multi-detector gas chromatography," J. Chromatogr. A, 1057(1-2), 177-183(2004).   DOI
4 Huang, P. M., and Fujii, R. Chapter 30 Selenium and Arsenic. In: Sparks, D. L. (ed) Methods of soil analysis, Part 3. Chemical method-SSSA book series no. 5. Segoe Rd., Madison, WI 53711, USA(1996).
5 정병간, 최정원, 윤을수, 윤정희, 김유학, "우리나라 밭 토양 화학적 특성," 한국토양비료학회지, 34(5), 326-332(2001).
6 Raven, K. P., Jain, A., and Loeppert, R. H., "Arsenite and arsenate adsorption on ferrihydrite: kinetics equilibrium and adsorption envelopes," Environ. Sci. Technol., 32(3), 344-349 (1998).   DOI   ScienceOn
7 구자공, 김경숙, 동종인, 박용하, 배우근, 양지원, 염익태, 윤석표, 이재영, 이주삼, 장윤영, 정재춘, 최상일, 황경엽, 황종식, 토양환 경공학, 1판, 향문사, 서울, p. 176(2007).
8 환경부, 오염토양 정화방법 가이드라인(2007).
9 양재의, 옥용식, 문덕현, "중금속 오염토양의 안정화 기술," 광해방지기술, 2(2), 121-142(2008).
10 US EPA, Treatment technologies for site cleanup: annual status report(twelfth edition), EPA 542-R-07-012(2007).
11 Ok, Y. S., Lee, H., Jung, J., Song, H., Chung, N., Lim, S., and Kim, J. G., "Chemical characterization and bioavailability of cadmium in artificially and naturally contaminated soils," Agric. Chem. Biotechnol., 47(3), 143-146(2004).
12 Kumpiene, J., Lagerkvist, A., and Maurice, C., "Stabilization of As, Cr, Cu, Pb and Zn in soil using amendments," Waste Management, 28(1), 215-225(2008).   DOI   ScienceOn
13 박인협, 서영광, 임전택, 이충일, "제강슬래그의 적용이 묘포 및 소나무림의 토양과 식물생장에 미치는 영향," 한국임학회지, 90(6), 699-706(2001).
14 임준택, 이인, 박인진, 이충일, 현규환, 권병선, 김학진, "논토양 벼재배에서 제강슬래그의 토양개량제로서의 시용 효과," 한국토양비료학회지, 32(3), 295-303(1999).
15 농업과학기술원, 토양 및 식물체 분석법(2000).
16 Novozamsky, I., Lexmond, T. M., and Houba, V. J. G., "A single extraction procedure of soil for evaluation of uptake of some heavy metals by plants," Int. J. Environ. Anal. Chem., 51(1-4), 47-58(1993).   DOI
17 환경부, 토양오염공정시험방법, 도서출판 동화기술(2007).
18 ISO, Soil quality, Extraction of Trace Elements Soluble in Aqua Regia, ISO 11466(1995).
19 SAS, SAS user's guide, version 9.1., SAS Institute Inc., Cary, North Carolina, USA(2004).
20 구성은, 황경진, 김동수, "제강슬래그 처리 및 재활용의 최적화를 위한 분쇄 특성에 관한 연구," 대한환경공학회지, 22(6), 1139-1148(2000).
21 Blakley, B. R., Clark, E. G., and Fairley, R., "Roxarsone (3-nitro-4-hydroxyphenylarsonic acid) poisoning in pigs," Can. Veterinary J., 31(5), 385-387(1990).
22 유경열, "Zero-Valent Iron(ZVI)에 의한 As의 불용화 기작," 농학 석사학위논문, 강원대학교(2003).
23 김대연, 김정규, "비소(Arsenic)에 의한 토양 오염과 복원기술," 생명자원연구, 12, 103-118(2004).
24 김명진, 안규홍, 정예진, "토양에서의 비소흡착: 반응속도 및 흡착평형," 대한환경공학회지, 25(4), 407-414(2003).
25 이효민, 최시내, 박송자, 황경엽, 조성용, 김선태, "폐광산 지역의 비소오염에 대한 복원목표 설정," 한국지하수토양환경학회지, 3(2), 13-29(1998).
26 US EPA, Drinking water standards for Arsenic, EPA 815-F-00-015(2001).
27 임정은, 문덕현, 김동진, 권오경, 양재의, 옥용식, "농축수산 폐기물(굴껍질 및 달걀껍질)을 이용한 비소 오염토양의 안정화 효율평가," 대한환경공학회지, 31(12), 1095-1104.   과학기술학회마을
28 Smedley, P. L., and Kinniburgh, D. G., "A review of the source, behavior and distribution of arsenic in natural waters," Appl. Geochem., 17(5), 517-568(2002).   DOI   ScienceOn
29 Berg, M., Tran, H. C., Nguyen, T. C., Pham, H. V., Schertenleib, R., and Giger, W., "Arsenic contamination of groundwater and drinking water in Vietnam: A human health threat," Environ. Sci. Technol., 35(13), 2621-2626(2001).   DOI   ScienceOn
30 방선백, Xiaoguang Meng, 방기웅, "0가 금속철을 이용한 비소처리에 있어서 용존산소와 pH가 미치는 영향에 대한 연구," 대한환경공학회지, 25(11), 1429-1435(2003).
31 Nachman, K. E., Mihalic, J. N., Burke, T. A., and Geyh, A. S., "Comparison of arsenic content in pelletized poultry house waste and biosolids fertilizer," Chemosphere, 71(3), 500-506(2007).
32 Garbarino, J. R., Bednar, A. J., Rutherford, D. W., Beyer, R. S., and Wershaw, R. L., "Environmental fate of roxarsone in poultry litter. I. Degradation of roxarsone during composting," Environ. Sci. Technol., 37(8), 1509-1514(2003).   DOI   ScienceOn
33 Jackson, B. P., Seaman, J. C., and Bertsch, P. M., "Fate of arsenic compounds in poultry litter upon land application," Chemosphere, 65(11), 2028-2034(2006).   DOI   ScienceOn
34 US EPA, Arsenic treatment technologies for soil, waste, and water, EPA 542-R-02-004(2002).
35 김태석, 김명진, "비소와 중금속으로 오염된 광미의 정화: 토양 세척에 의한 비소 제거," 대한환경공학회지, 30(8), 808-816(2008).
36 최영무, 최원호, 김정환, 박주양, "층상이중 수산화물을 이용한 5가 비소 흡착 특성," 대한토목학회지, 29(1B), 91-96(2009).
37 유경열, 옥용식, 양재의, "영가철(Zerovalent Iron)을 이용한 수용액 중 비소(V)의 불용화," 한국환경농학회지, 26(3), 197-203(2007).   과학기술학회마을