본 연구는 규소슬래그의 흡착제로서의 주요한 특성을 분석하고 규소슬래그와 수용상 비소와의 흡착특성을 규명하여 규소슬래그의 비소 흡착제로서의 활용가능성을 평가하고자 수행되었다. 규소슬래그의 비표면적은 6.71 $m^2/g$으로 다른 슬래그들에 비해 다소 높았으나, 비소 제어에 널리 이용되고 있는 철 (산수)산화물들에 비해서는 상대적으로 낮았다. 전위차 적정법(potentiometric titration)에 의해 측정된 영전하점(point of zero salt effect, PZSE)은 7.3으로 비교적 높아 주로 음이온으로 존재하는 비소의 흡착에 유리한 특성인 것으로 조사되었다. 흡착등온식을 알아보기 위한 실험결과, 두 비소 종 모두 Langmuir 등온식이 규소슬래그와의 흡착특성을 가장 잘 모사한 것으로 평가되었다. pH에 따른 흡착특성은 3가 비소는 pH 7에서 최대 흡착량을 보였고, 그 외 pH 조건에서는 흡착량이 현저하게 감소하였다. 5가 비소의 최대 흡착량은 가장 낮은 pH 조건(pH 4)에서 나타났으며, pH가 증가함에 따라 흡착량이 지속적으로 감소하는 것으로 조사되었다. 흡착반응속도를 알아보기 위한 실험결과, 3가 비소의 흡착은 2시간 이내에 평형에 도달하였으며, 5가 비소의 경우에는 8시간 이내에 평형에 도달하였다. 그리고 비소의 화학종과 관계없이 규소슬래그와의 흡착반응속도는 유사이차 반응속도모델이 가장 적합한 것으로 나타났다. 동일한 실험 조건에서 5가 비소가 3가 비소 보다 약 6배가량 큰 규소슬래그와의 친화력을 나타났다.

This study was initiated to evaluate the applicability of Si slag as an adsorbent via investigation of the main properties of Si slag as an adsorbent aw well as characterization of adsorption features between aqueous arsenic and Si slag. The specific surface area of Si slag was measured to be 6.71 $m^2/g$ which seems to be slightly higher than those of other slags, but relatively lower than those of iron (oxyhydr)oxides extensively used for arsenic controlling processes. The point of zero salt effect (PZSE) of Si slag determined by potentiometric titration appeared to be comparatively high (7.3), indicating the Si slag may be favorably used for adsorption of arsenic which predominantly exists as an oxy-anions. The results of adsorption isotherm indicate that regardless of arsenic species, Langmuir-type isotherm is the most suitable to simulate the adsorption of arsenic onto Si slag. With regard to pH-dependence of arsenic adsorption, the adsorption maxima of arsenite was centered at pH 7, and the adsorption was remarkably decreased in the other pH conditions. In the case of arsenate, on the other hand, the adsorption was highest at the lowest pH (4.0) and then gradually decreased with the increase of pH. Based on the results of kinetic experiments, it is likely that the adsorption of arsenite approached equilibrium within 2 hr, but it took about 8 hr for arsenate adsorption to be equilibrated. In addition, the Pseudo second order was evaluated to be most consistent with the empirical data of arsenic adsorption onto Si slag in this study. Under identical conditions, the affinity of arsenate onto Si slag was estimated to be nearly 6 times higher than that of arsenite.

1 김순오, "침철석(goethite)과 비소의 흡착반응" 한국광물학회 22 (22): 177-189, 2009

2 이광헌, "제강슬래그의 카드뮴 제거능 평가 및 필요반응시간 결정" 한국지반공학회 27 (27): 5-12, 2011

3 이민희, "제강슬래그와 석회석을 이용한 비소오염 농경지 토양 안정화 연구" 대한자원환경지질학회 43 (43): 305-314, 2010

4 손정호, "제강슬래그와 CaO를 이용한 폐광산 주변 중금속 오염 농경지 토양의 안정화 처리 연구" 한국지하수토양환경학회 14 (14): 78-86, 2009

5 정명채, "제강슬래그, 우분 및 석회석을 활용한 폐 석탄광의 산성광산배수 처리" 한국지하수토양환경학회 10 (10): 16-23, 2005

6 김성희, "적철석(Hematite) 표면의 비소 흡착 특성" 한국광물학회 25 (25): 197-210, 2012

7 정현수, "자철석의 비소에 대한 흡착특성 연구" 한국광물학회 21 (21): 423-432, 2008

8 정영일, "비소의 Two-Line Ferrihydrite에 대한 흡착반응" 한국광물학회 21 (21): 227-237, 2008

9 김은협, "모사해수 조건에서 회분식 실험을 이용한 제강슬래그의 카드뮴 흡착 특성 평가" 한국지반공학회 27 (27): 43-50, 2011

10 이우춘, "레피도크로사이트(lepidocrocite) 표면의 비소 흡착 특성 규명" 대한자원환경지질학회 42 (42): 95-105, 2009

11 오참뜻, "등온 및 동적 흡착 실험을 통한 제강 슬래그의 비소 흡착 특성" 한국지반공학회 26 (26): 37-45, 2010

12 황의환, "급냉 제강슬래그를 재활용한 EVA-폴리머 시멘트 모르타르의 특성" 한국공업화학회 19 (19): 652-660, 2008

13 Marek, K., "pH-dependent surface charging and points of zero charge. IV. Update and new approach" 337 : 439-448, 2009

14 이우춘, "pH 4와 10에서의 3가 비소와 Two-Line Ferrihydrite의 표면반응에 대한 X선 흡수 분광 연구" 한국광물학회 24 (24): 73-82, 2011

15 Kraepiel, A. M. L., "on the acid-base chemistry of permanently charged minerals" 32 : 2829-2838, 1998

16 Waybrant, K. R., "Treatment of mine drainage using permeable reactive barriers: Column experiments" 36 : 1349-1356, 2002

17 Shin, D. H., "Treatment of acid mine drainage(AMD) by limestone marine shells, slag" 423-430, 2003

18 Choi, S. -W., "The present situation of production and utilization of steel slag in korea and other countries" 19 : 28-33, 2007

19 Davis, J.A., "Surface complexation modeling in aqueous geochemistry, In Reviews in mineralogy and geochemistry, v.23" 170-260, 1990

20 Singh, T.S., "Solidification/stabilization of arsenic containing solid wastes using portland cement, fly ash and polymeric materials" 131 : 29-36, 2006

21 Keiko, S., "Removal of arsenate in acid mine drainage by a permeable reactive barrier bearing Granulated Blast Furnace Slag: Column study" 49 : 835-844, 2008

22 Ponder, S. M., "Remediation of Cr(VI) and Pb(II) aqueous solutions using supported, nanoscale zero-valent iron" 34 : 2564-2569, 2000

23 Palfy, P., "Processing of arsenic waste by precipitation and solidification" 19 : 55-59, 1999

24 Nowack, B., "Modeling the adsorption of metal-EDTA complexes onto oxides" 30 : 2397-2405, 1996

25 Marshall, L., "Management of Sulfidic Mine Wastes and Acid Drainage" Australian Centre for Mining Environmental Research 18-, 1999

26 Carrasco, N., "Low concentration of surfactants enhance siderophore-promoted dissolution of goethite" 37 : 3633-3638, 2007

27 Sparks, D. L., "Kinetics and mechanisms of chemical reactions at the soil/mineral water interface, In Soil physical chemistry. 2nd(ed.)" CRC press 135-191, 1999

28 Schwertmann U., "Iron oxides in the laboratory: preparation and characterization" Wiley-VCH Publishers 188-, 2000

29 Nielsen, U. G., "Investigating sorpton on iron-oxyhydroxide soil minerals by solid-statd NMR spectroscopy: A 6Li MAS NMR study of adsorption and adsorption on goethite" 109 : 18310-18315, 2005

30 Rietra, R. P. J. J., "Interaction between calcium and phosphate adsorption on goethite" 35 : 3369-3374, 2001

31 Bai, B., "In situ mechanistic study of SDS adsorption on hematite for optimized froth flotation" 43 : 5326-5338, 2004

32 Phillip, E., "Growth of sulfate- reducing bacteria under acidic conditions in an upflow anaerobic bioreactor as a treatment system for acid mine drainage" 32 : 3724-3730, 1998

33 Sparks, D. L., "Environmental Soil Chemistry" Academic Press 207-244, 2003

34 Singh, U., "Electrochemistry of the double layer: Principles and applications to soils, In Soil physical chemistry" CRC Press 1-56, 1998

35 He, Y.T., "Cr(VI) reduction and immobilization by magnetite under alkaline pH conditions: The role of passivation" 39 : 4499-4504, 2005

36 Lowry, G.V., "Congener-specific dechlorination of dissolved PCBs by microscale and nanoscale zerovalent iron in a water/methanol solution" 38 : 5208-5216, 2004

37 Lee, S. E., "Comparison of the ion adsorption method, potentiometric titration, and backtitration technique for surface charge measurement in Ultisol, Alfiso, and Inceptisol" 26 : 160-171, 1993

38 Yang, J. E., "Comparative assessment of the half-lives of benfuresate and oxolinic acid estimated from kinetic models under field soil condition" 14 : 302-311, 1995

39 Stumm, W., "Chemistry of the Solid-water interface" John Wiley & Sons 1992

40 Harris, M.A., "Bioremediation of acid mine drainage using decomposable plant material in a constant flow bioreactor" 40 : 1192-1204, 2001

41 Williams, J.W., "Bacterial resistance and detoxification of heavy metals" 6 : 530-537, 1984

42 Michelle, L.C., "Association of cadmium with MnO2 particles generated during permanganate oxidation" 38 : 887-894, 2004

43 Roman-Ross, G., "Arsenite sorption and co-precipitation with calcite" 233 : 328-336, 2006

44 Jain, A., "Arsenite and arsenate adsorption on ferrihydrite : Surface charge reduction and net OH- release stoichiometry" 33 : 1179-1184, 1999

45 Raven, K. P., "Arsenite and arsenate adsorption on ferrigydrite: Kinetics, equilibrium, and adsorption envelopes" 32 : 344-349, 1998

46 La force, M. J., "Arsenic speciation, seansonal transformations, and co-distribution with iron in a mine waste-influenced Palustrine Emegent Wetland" 34 : 3937-3943, 2000

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

48 Mamindy-Pajany, Y., "Arsenic adsorption onto hematite and goethite" 12 : 876-881, 2009

49 Inskeep, W. P., "Arsenic (V)/(III) cycling in soils and natural water: chemical and microbiological processes, In Environmental chemistry of arsenic" Marcel Dekker 183-215, 2002

50 Park, K. -S., "Application of steel-making(BOF) slag for in-situ remediation of subaqueous contaminated sediments" 13 : 310-322, 2006

51 David, S., "Application of permeable reactive barriers for treating mine drainage and dissolved metals in groundwater" 39-44, 2004

52 Jonsson, C. M., "Adsorption of glyphosate on goethite(α- FeOOH): Surface complexation modeling combining spectroscopic and adsorption data" 42 : 2464-2469, 2008

53 Du, Q., "Acidbase properties of aqueous illite surfaces" 187 : 221-231, 1997

54 Kwon, S.-D., "A study on the treatment of the acid mine drainage using the steel mill slag" 6 : 206-212, 1999