Sorption characteristics of arsenic on furnace slag were investigated to remove arsenic from groundwater using furnace slag, which is industrial waste generated from steel company. Adsorption isotherm experiments and kinetic sorption experiments were performed and the chemical characteristics of supernatants from these experiments were analyzed. Results showed that all supernatants were alkaline (above pH 9) and the highest ion concentration in the solution was found with calcium (30～50 mg/L). Results of adsorption isotherms were more adequately described by the Freundlich model than Langmuir model. From adsorption isotherms experiments, it was noted that the adsorption amount of As(V) was 87% higher than that of As(III). Results of kinetic sorption experiments were more properly fitted by pseudo second order (PSO) model than pseudo first order model. Equilibrium adsorption amount (qe) and relaxation time (tr) calculated from PSO model increased with initial concentration of arsenic. Equilibrium adsorption amount of As(V) was higher than that of As(III) and relaxation time of As(V) was shorter than that of As(III). Adsorption isotherm results could be predicted by kinetic adsorption results, since equilibrium adsorption amount calculated through PSO model generally agreed with equilibrium adsorption amount measured from adsorption isotherm.

1 환경부, "환경백서"

2 송형명, "폐타이어 활성탄을 이용한 중금속의 흡착특성" 한국폐기물자원순환학회 27 (27): 111-121, 2010

3 전대영, "폐슬러지와 폐굴껍질의 중금속 흡착특성" 한국환경과학회 15 (15): 1053-1059, 2006

4 환경부, "폐기물관리법 시행규칙"

5 환경부, "폐기물공정시험방법"

6 환경관리공단, "폐금속광산 토양오염실태 종합보고서(158개 광산 종합)"

7 한국철강협회, "철강슬래그 2009년 재활용실적 및 2010년계획"

8 장윤영, "철 및 망간코팅사 충진비를 달리한 여과시스템에서 3가 비소 제거의 최적 조건" 대한환경공학회 28 (28): 1186-1191, 2006

9 이희용, "철 및 망간 산화물로 코팅된 입자활성탄을 이용한 수용액 중 As(ⅢI) 및 As(Ⅴ)의 제거" 대한환경공학회 31 (31): 613-620, 2009

10 구성은, "제강슬래그 처리 및 재활용의최적화를 위한 분쇄 특성에 관한 연구" 22 (22): 1139-1149, 2000

11 김병권, "산화철 및 산화망간이 동시에 코팅된 모래 매질을 이용한 비소오염 제거특성 연구" 대한환경공학회 31 (31): 473-482, 2009

12 이현용, "밤 부산물의 수용액 중 중금속 흡착 특성" 한국환경농학회 28 (28): 69-74, 2009

13 최성대, "기술기사: 반응벽체의 수리지질학적 거동에 대한 수치해석 사례" 23 (23): 23-31, 2007

14 이진수, "금속광산지역 독성 중금속원소들의 인체 위해성 평가" 대한자원환경지질학회 37 (37): 73-86, 2004

15 정명채, "국내 휴/폐광 금속광산 주변의 중금속 환경오염 평가" 대한자원환경지질학회 37 (37): 21-33, 2004

16 정명채, "국내 휴/폐광 금속광산 주변의 중금속 환경오염 평가" 대한자원환경지질학회 37 (37): 21-33, 2004

17 안주성, "광산 폐기물에 의한 비소 및 중금속의 지표하부 유출과 격리저장 처리기법" 38 (38): 246-256, 2001

18 이민희, "고로폐광산 주변 농경지 토양 및 하천 퇴적토의 중금속 오염 분포 및 복원 대책 설계" 대한자원환경지질학회 36 (36): 89-101, 2003

19 Lagergren, S, "Zur theorie der sogenannten adsorption geloster stoffe" 24 (24): 1-39, 1898

20 Dimitrova, S. V, "Use of granular slag columns for lead removal" 36 (36): 4001-4008, 2002

21 Weng, C. H, "Treatment of metal industrial waste water by fly ash and cement fixation" 120 (120): 1470-1487, 1994

22 Bard, A. J, "Standard potentials in aqueous solutions" Marcel Dekker 162 -, 1985

23 Dutré, V, "Solidification/stabilization of arsenic-containing waste: leach tests and behavior of arsenic in the leachate" 15 (15): 55-62, 1995

24 Ho, Y. S, "Pseudo-second order model for sorption processes" 34 (34): 451-465, 1999

25 Gupta, V. K, "Process development for the removal of lead and chromium from aqueous solutions using red mud-an aluminium industry waste" 35 (35): 1125-1134, 2001

26 Lan, Y. Z, "Phosphorus removal using steel slag" 34 (34): 259-265, 2006

27 R. Thiruvenkatachari, "Permeable reactive barrier for groundwater remediation" 한국공업화학회 14 (14): 145-156, 2008

28 Yu, L, "New insights into pseudo-second-order kinetic equation for adsorption" 320 (320): 275-278, 2008

29 정재현, "MnO2-코팅 모래흡착제 제조 및 As(III) 산화처리 적용" 대한환경공학회 28 (28): 54-60, 2006

30 Dimitrova, S. V, "Metal sorption on blast-furnace slag" 30 (30): 228-232, 1999

31 Azizian, S, "Kinetic models of sorption: a theoretical analysis" 276 (276): 47-52, 2004

32 Zhang, F, "Iron oxide-loaded slag for arsenic removal from aqueous system" 60 (60): 319-325, 2005

33 MacRae, C. W. T, "In situ removal of arsenic from groundwater using permeable reactive barriers: a laboratory study" 601-609, 1999

34 USEPA, "Green remediation: Incorporating sustainable environmental practices into remediation of contaminated site" U.S. Environmental Protection Agency Office of Solid Waste and Emergency Response 2008

35 Oh, J. K, "Evaluation of contamination at closed mine and application methods of tailing wastes In Symposium on the remediation and application methods of environmental pollution around abandoned mine" 97 (97): 15-51, 1997

36 Gavaskar, A. R, "Design and construction techniques for permeable reactive barriers" 68 (68): 41-71, 1999

37 Yoshida, T, "Chronic health effects in people exposed to arsenic via the drinking water: doseresponse relationships in review" 198 (198): 243-252, 2004

38 Lee, H. Y, "Biosorption technology for removal of heavy metals from wastewater : a literature review" 6 (6): 15-24, 2008

39 Tournassat, C, "Arsenic(III) oxidation by birnessite and precipitation of manganese (II) arsenate" 36 (36): 493-500, 2002

40 Roberts, L. C, "Arsenic removal with iron(II) and iron(III) in waters with high silicate and phosphate concentrations" 38 (38): 307-315, 2004

41 Ahn, J, "Arsenic removal using steel manufacturing byproducts as permeable reactive materials in mine tailing containment systems" 37 (37): 2478-2488, 2003

42 Altundogan, H. S, "Arsenic removal from aqueous solutions by adsorption on red mud" 20 (20): 761-767, 2000

43 Bothe, J. V, "Arsenic immobilization by calcium arsenate formation" 33 (33): 3806-3811, 1999

44 USEPA, "Arsenic and Clarifications to compliance and New Source Monitoring Rule: A Quick Reference Guide"

45 Ferguson, J. F, "A review of the arsenic cycle in natural waters" 6 (6): 1259-1274, 1972