합성된 레피도크로사이트(lepidocrocite)에 대한 비소의 흡착특성을 규명하기 위하여 체계적인 연구를 수행하였다. 본 연구에서 합성된 레피도크로사이트는 $94.8\;g/m^2$의 큰 비표면적을 가졌으며, 전위차 적정법(potentiometric titration)에 의해 측정된 영전하점(point of zero charge, PZC)은 6.57로 나타났는데, 레피도크로사이트의 비소에 대한 높은 제거능은 이러한 특성들에 기인한 것으로 판단된다. pH $2.0{\sim}12$ 범위에서 3가(아비산염 형태) 비소가 5가(비산염 형태) 비소보다 합성된 레피도크로사이트에 대한 흡착력이 크게 나타나서 3가 비소가 5가 비소보다 레피도크로사이트에 대한 친화력이 더 크다는 것을 알 수 있었다. 5가 비소의 흡착은 pH가 2.0에서 12까지 증가하면서 지속적으로 감소한 반면, 3가 비소는 pH가 8.0까지 증가할 때까지는 흡착도 증가하다가 그 이후의 높은 pH조건에서는 흡착이 급격히 감소하는 것으로 조사되었다. 이는 pH에 따라서 레피도크로사이트의 표면전하 특성과 두 비소 종의 존재형태가 변화하기 때문인 것으로 판단된다. 흡착 반응속도에 대한 실험 결과에 의하면, 두 비소 종 모두 4시간 이내에 빠르게 흡착이 완료되는 것으로 나타났는데, 이러한 결과는 레피도크로사이트에 의한 비소의 제거는 주로 흡착반응 이라는 것을 입증한다. 이와 더불어 본 연구결과는 power function과 elovich 모델이 레피도크로사이트에 대한 두 비소 화학종의 흡착반응속도를 모사하는데 가장 적합한 것으로 조사되었다.

Systematic studies are performed for arsenic adsorption on synthesized lepidocrocite. The synthesized lepidocrocite with high surface area of $94.8\;g/m^2$ has shown that the point of zero charge(PZC) is 6.57 determined by potentiometric titration, suggestive of high capacity of arsenic removal. Results show that arsenite[As(III)] uptake by synthesized lepidocrocite is greater than that of arsenate[As(V)] at pH $2{\sim}12$, indicating that the lepidocrocite has high affinity toward arsenite rather than arsenate. Adsorption of arsenate decreases with increasing pH from 2 to 12, whereas arsenite sorption increases until pH 8.0, and then decreases dramatically with increasing pH, suggesting that changes in surface charge of the lepidocrocite as a function of pH playa important role in aresinc uptake by the lepidocrocite. Upon kinetic experiments, our results demonstrate that both arsenite and arsenate sorption on the lepidocrocite increases rapidly for the first 4 h followed by little changes during the duration of the experiment, showing that adsorption plays a key role in aresenic uptake by the lepidocrocite. Our results also show that power function and elovich models are the best fit for the adsorption kinetics of arsenite and aesenate on the lepidocrocite.

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

2 안주성, "자연적 지하수 비소오염의 국내외 산출특성" 대한자원환경지질학회 38 (38): 547-561, 2005

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

4 Katsoyiannis, A., "pH dependence of fenton reagent generation and As(III) oxidation and removal by corrosion of zero valent iron in aerated water" 42 : 7424-7430, 2008

5 Schwertmann, U, "oxides in the laboratory" Wiley-VCH Verlag GmbH 188-, 2000

6 Melitas, N, "Understanding soluble arsenate removal kinetics by zerovalent iron media" 36 : 2074-2081, 2002

7 Sposito, G, "The surface chemistry of soils" Oxford Univesity Press 234-, 1984

8 Cho. H.G,, "Surface chemical properties of the Youngdong illite ore: The pH of zero proton charge and surface site density" 14 : 12-20, 2001

9 Randall, S.R, "Sorption of As(V) on green rust( ) and lepidocrocite(γ-FeOOH): Surface complexes from EXAFS spectroscopy" 65 : 1015-1023, 2001

10 Sparks, D. L, "Soil physical chemistry(2ed.)" CRC Press 405-, 1999

11 Fendorf, S.E, "Pulsed-flow kinetic analysis of solid-phase transformations in mineral suspensions using XANES spectroscopy: Oxidation of FeS to γ-FeOOH" 214 : 34-, 1997

12 Kim, S.O, "Preliminary X-ray absorption spectroscopic study on surface complexation of arsenic with zerovalent iron and iron (oxyhydr)oxides" 131-134, 2007

13 Herbert, R.B, "Precipitation of Fe oxyhydroxides and jarosite from acidic groundwater" 117 : 81-85, 1995

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

15 Carrasco, N., "Low concentrations of surfactants enhanced siderophore-promoted dissolution of goethite" 37 : 3633-3638, 2007

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

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

18 USEPA., "Integrated Risk Information System"

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

20 Inskeep, W.P, "Environmental Chemistry of Arsenic" Marcel Dekker 183-215, 2002

21 Farrel, J, "Electrochemical and spectroscopic study of arsenate removal from water using zero-valent iron media, Environ" 35 : 2026-2032, 2001

22 Ona-Nguema, G, "EXAFS analysis of arsenite adsorption onto two-line ferrihydrite, hematite, goethite, and lepidocrocite" 39 : 939-944, 2005

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

24 Peacock, C.L, "Copper(II) sorption onto goethite, hematite and lepidocrocite: A surface complexation model based on ab initio molecular geometries and EXAFS spectroscopy" 68 : 2623-2637, 2004

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

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

27 Dixit, S., "Comparison of arsenic(V) and arsenic(III) sorption onto iron oxide minerals: Implications for arsenic mobility, Environ" 37 : 4182-4189, 2003

28 Ona-Nguema, G, "Arsenite sequestration at the surface of nano-Fe(OH)2, ferrous-carbonate hydroxide, and greenrust after bioreduction of arsenic-sorbed lepidocrocite by Shewanella putrefaciens" 73 : 1359-1381, 2009

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

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

31 Manning, B.A, "Arsenic(III) and arsenic(V) relations with zerovalent iron corrosion products" 36 : 5455-5461, 2002

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

33 Giménez, J, "Arsenic sorption onto natural hematite, magnetite, and goethite" 141 : 575-580, 2007

34 Su, C, "Arsenate and arsenite removal by zerovalent iron: Kinetics, redox transformation, and implications for in situ groundwater remediation" 35 : 1487-1492, 2001

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

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

37 방선백, "A Review of Arsenic Interactions with Anions and Iron Hydroxides" 대한환경공학회 9 (9): 184-192, 2004