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Comparison of Some Physicochemical Properties and Adsorption of Organic Cations between Ca- and Na-bentonites  

고상모 (한국지질자원연구원 지질연구부)
김자영 (한국지질자원연구원 지질연구부)
Publication Information
Journal of the Mineralogical Society of Korea / v.15, no.4, 2002 , pp. 243-257 More about this Journal
Abstract
Ca-type and Na-type bentonites show the great difference of some physicochemical properties. Na exchanged bentonite is mainly used for the foundry and construction materials in domestic utilization. This study tries to identify in detail the differences of some physicochemical properties and thermal properties between Ca-type and Na-type bentonites. Also the adsorption behavior and interlayer expansion for the HDTMA (Hexadecyltrimethylammonium) exchanged and CP (Cetylprydinium) exchanged Ca-type and Na-type bentonites were compared. Na-type bentonite shows the strong alkaline property, high viscosity and swelling compared to Ca-type bentonite. However, two types are very similar for the cation exchange capacity and MB (Methylene Blue) adsorption. The decomposition of adsorbed and interlayer water of Na-type bentonite is caused in the lower temperature than Ca-type bentonite. And Ca-type bentonite shows the decomposition of structural water in the lower temperature than Na-type bentonite. The interlayer expansion of montmorillonite resulted to the intercalation of HDTMA and CP into bentonite is so strongly caused from 12~15 $\AA$ to $40\AA$ (basal spacing). HDTMA-bentonite is almost expanded to $37~38\AA$ when 200% CEC equivalent amount of HDTMA is added, and CP-bentonite is fullly expanded to 40 $\AA$ in the 140% CEC equivalent amount of CP It means that CP causes the stronger interlayer expansion of montmorillonite and easier adsorption than HDTMA. Adsorption behaviors of CP into bentonite is so stable and continuously sorbed in the proportion to the treatment of amount until 200% of the CEC equivalents. CP-bentonite shows the same adsorption behavior regardless of Ca-type or Na-type montmorillonite.
Keywords
Ca-type bentonite; Na-type bentonite; HDTMA; CP; CEC; interlayer expansion; adsorption;
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1 高木哲一,内藤-樹,고상모, 김문영 (2001) 일본 벤토나이트의 광상 및 공업현황. 광물과산업, 14, 9-17.
2 문희수 (1995) 점토광물학, 민음사.
3 Boyd, S.A , Mortland, M.M., and Chiou C.T. (1988b) Sorption characteristic s of organic comp ounds on Hexadecy ltrimethy lammonium-smectite. Soil Sci . Soc. Am. J., 52, 652-657.
4 Johnston, C.T. (1996) Sorption of organic compounds on clay mineral s: A surface functional group approach. In: Sawhney, B.L. (ed.), Organic pollutants in the environment, ems work shop lectures, 8, The Clay Minerals Society, Boulder, CO, USA,2-44.
5 Koh, S.M. and Dixon, J.B. (2001) Praparation and application of organo-minerals as sorbents of phenol, benzene and toluene. Appl. Clay Sci., 18,111-122.
6 Lee J., Mortland, M.M., Chiou, C.T., Kile, D.E., and Boyd, S.A. (1990) Adsorption of benzene, toluene, and xylene by two tetramethylammonium-smectites having different charge densities. Clays and Clay Minerals,38,113-120 .
7 Mortland, M.M. (1970) Clay-organic complexes and interactions. In: Advances in agronomy, 12. 75-117.   DOI
8 Brixie J.M. and Boyd, S.A (1994) Treatment of contaminated soils with organoclays to reduce leach able pentachlorophenol (Organic chemicals in the environment). J. Environ. Qual ., 23, 1283-1290.
9 Jaynes, W.F. and Boyd, S.A. (1991) Clay mineral type and organic compound sorption by hexadecyltrimeth ylammonium-exchanged clays. Soil Sci. Soc. Am. J., 55, 43-48.
10 Dultz, S. and Bors, J. (2000) Organophilic bentonites as adsorbents for rad ionuclides (II. Chemical and mineralogical properties of HDPy-montmorillonite.) Appl. Clay Sci., 16, 15-29.
11 Montgomery, D.M., Sollars, C.J. Sheriff, T.S., and Perry, R. (1988) Organophilic clays for the successful stabilization/solidification of problematic industrial wastes. Environ. Technol. Lett., 9,1403-1412.
12 Bors, J., Dultz, S., and Riebe, B. (2000) Organophilic bentonites as adsorbent s for radionuclides (I. Adsorption of ionic fission products). Appl. Clay Sci.,16,1-13.
13 Jaynes, W.F. and Vance, G.F. (1996) BTEX sorption by organo-c1ays: cosorptive enhancement and equivalence of interlayer complexes. Soil Sci. Soc. Am. J., 60, 1742-1749.
14 이상현, 방성완, 서전형(2000) 국내 벤토나이트의 각산업에서의 활용 및 그 현황. 제 1회 산업광물 심포지움 논문요약집, ‘벤토나이트 및 그 응용’ 중에서, 40-50.
15 Boyd, SA, Lee J., and Mortl and, M.M. (1988a) Attenuating organ ic contaminant mob ility by soil mod ification. Nature, 333, 345-347.
16 Smith. J.A. and Jaffe, P.R. (1994) Adsorptive selectivity of organic-cation -modified bentonite for nonionic organic contaminants. Water, Air and Soil Pollution, 72. 205-211.
17 Mc Bride, M.B. (1989) Surface chemistry of soil minerals. In: Dixon, J.B. and Weed, S.B. (eds.), Mineral s in soil environments, Soil Sci. Soc. Arn., Book Series I, Madison, Wisconsin, USA, 35-88.
18 Mortland, M.M., Shaobai, S., and Boyd, SA (1986) Clay-organic complexes as adsorbents for phenol and chlorophenols. Clays and Clay Minerals, 34,581-585.
19 Srinivasan, K.R., Fogler, H.S., Nolan, T., and Schultz (1985) The removal or trace levels or dioxins from water by sorption on modified clay. Environ. Progress, 4, 239-244.
20 Lagaly, G. and Weiss, A. (1969) Determination of the clay charge in mica-type layer silicates. In: Proc. Int. Clay Conf. Tokyo, I, 61-80.
21 고상모, 손병국, 성민섭 (2002) 국내 벤토나이트의 물성과 그 요인에 관하여. 한국광물학회. 한국암석학회 공동학술발표회 요약집, 90-92.
22 Deng, Y. and Dixon J.B. (2002) Soil Organic matter and organic-mineral interactions. In: Dixon, J.B.and Schulze, D.G. (eds.), Soil Mineralogy with Environmental Applications, Soil Sci. Soc. Am.,Book Series 7, Madison, Wisconsin, USA, 69-107.
23 Sheriff, T.S., Sollars, C.J., Montgomery, D., and Perry, R. (1987) Modified clays for organic waste disposal. Environ. Tcchnol, I.ctt., 8, 501-514.
24 Srinivasan. K.R. and Fogler, II.S. (1989) Usc or modified clays for the removal and disposal of chlorinated dioxins and other priority pollutants form industrial waste waters. Cosrnoshere, 18,333-342.
25 Alther, G.R. (1998) Organocl ay systems extend the life of activated carbon and membrane-based polishing systems by reducing or eliminating organic fouling . Industrial Wastewater.
26 Boyd, S.A., Shaobai, S., Lee, J., and Mortland, M.M. (1988c) Pentachlorophenol sorption by organoclays.Clays and Clay Minerals, 36, 125-130.
27 Paterson, E. and Swaffield, R. (1987) Thermal analysis. In: Wilson, M.J. (ed.), A handbook of determinative method s in clay mineralogy, Blackie,99-132.
28 Baver, L.D. and Winterkorn , H.F. (1935) Sorption of liquid s by soil colloids (II). Soil Sci., 40, 403-419.
29 Borchardt, G. (1989) Smectites. In: Dixon, J.B. and Weed, S.B. (eds.), Minerals in soil environments, Soil Sci . Soc. Arn., Book Series I, Madi son,Wiscon sin, USA, 675-718.
30 Lawrence, M.A.M ., Kukkadapu, R.K., and Boyd,S.A. (1998) Adsorption of phenol and chlorinated phenol s form aqueou s solution by tetrad-ecylammonium- and tertramethylphosphonium-exchanged montmorillonite. Appl. Clay Sci., 13, 13-20.