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Crude Kaolin Dissolution in the Absence and Presence of Sodium Poly(Acrylic Acid), Sodium Hexametaphosphate, and Sodium Silicate under Different Experimental Conditions

Published online by Cambridge University Press:  01 January 2024

Feridun Demir*
Affiliation:
Department of Chemical Engineering, Osmaniye Korkut Ata University, Osmaniye 80000, Turkey Department of Chemical Engineering, University of Florida, Gainesville, Florida 32611-6005, USA
*
*E-mail address of corresponding author: [email protected], [email protected]
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Abstract

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The influence of anionic dispersing agents, such as sodium poly(acrylic acid), sodium hexametaphosphate, and sodium silicate on the dissolution of crude kaolin was examined by measuring the dissolved metals produced in the absence and presence of dispersing agents. For this purpose, the rheological and structural changes caused by the dissolution of kaolin metal constituents were studied in batch mode using several parameters, namely, solids (wt.%), pH, contact time (aging), and dispersing agent dose. A noteworthy increase in kaolin dissolution was caused by the presence of dispersing agents, particularly poly(acrylic acid) and sodium hexametaphosphate. These agents produced conspicuously large amounts of dissolved Al in comparison to the other experimental treatments. Little dissolved Si was measured under similar conditions in distilled water, but the amount of Si released using dispersing agents was nearly double that observed in distilled water only. Excess dispersing agents interacted with kaolin and dissolved accessory elements in the kaolin (i.e. Fe, Ca, Mg) and thus released enough Fe to form a stable Fe—dispersant complex. The present study showed that this phenomenon also contributed to a significant increase in the release of dissolved Al and Si through complexation.

Type
Article
Copyright
Copyright © Clay Minerals Society 2016

Footnotes

This paper is published as part of a special section on the subject of ‘Developments and applications of quantitative analysis to clay-bearing materials, incorporating The Reynolds Cup School’, arising out of presentations made during the 2015 Clay Minerals Society-Euroclay Conference held in Edinburgh, UK.

References

Altiokka, M.R. and Hoşgún, H.L., 2003 Investigation of the dissolution kinetics of kaolin in HCl solution Hydrometallurgy 68 7781.CrossRefGoogle Scholar
Amorós, J.L. Beltrán, V. Sanz, V. and Jarque, J.C., 2010 Electrokinetic and rheological properties of highly concentrated kaolin dispersions: Influence of particle volume fraction and dispersant concentration Applied Clay Science 49 3343.CrossRefGoogle Scholar
Andreola, F. Castellini, E. Manfredini, T. and Romagnoli, M., 2004 The role of sodium hexametaphosphate in the dissolution process of kaolinite and kaolin Journal of the European Ceramic Society 24 21132124.CrossRefGoogle Scholar
Andreola, F. Romagnoli, M.C. Castellini, E. Lusvardi, G. and Menabue, L., 2006 Role of the surface treatment in the deflocculation of kaolinite Journal of the American Ceramic Society 89 11071109.CrossRefGoogle Scholar
Andreola, F. Castellini, E. Lusvardi, G. Menabue, L. and Romagnoli, M., 2007 Release of ions from kaolinite dispersed in deflocculant solutions Applied Clay Science 36 271278.CrossRefGoogle Scholar
Ayadi, A.J. Pagnoux, C. and Baklouti, S., 2011 Kaolinpoly(methacrylic) acid interaction: polymer conformation and rheological behavior Comptes Rendus Chimie 14 456461.CrossRefGoogle Scholar
Benchabane, A. and Bekkour, K., 2006 Effects of anionic additives on the rheological behavior of aqueous calcium montmorillonite Rheologica Acta 45 425434.CrossRefGoogle Scholar
Bossard, F. Moan, M. and Aubry, T., 2007 Linear and nonlinear viscoelastic behavior of very concentrated platelike kaolin suspensions Journal of Rheology 51 12531270.CrossRefGoogle Scholar
Carroll, S.A. and Walther, J.V., 1990 Kaolinite dissolution at 25°, 60°, and 80°C American Journal of Science 290 797810.CrossRefGoogle Scholar
Carroll-Webb, S.A. and Walther, J.V., 1988 A surface complex reaction model for the pH-dependence of corundum and kaolinite dissolution rates Geochimica et Cosmochimica Acta 52 26092623.CrossRefGoogle Scholar
Chin, P-KF and Mills, G.L., 1991 Kinetics and mechanism of kaolinite dissolution: Effect of organic ligands Chemical Geology 90 307317.CrossRefGoogle Scholar
Demir, F., 2015 Experimental studies on the desorption of adsorbed sodium poly(acrylic acid) from crude kaolin particles Applied Clay Science 105-106 4147.CrossRefGoogle Scholar
Desai, H. Biswal, N.R. and Paria, S., 2010 Rheological behavior of pyrophyllite-water slurry in the presence of anionic, cationic, and nonionic surfactants Industrial & Engineering Chemistry Research 49 54005406.CrossRefGoogle Scholar
Devidal, J.L. Schott, J. and Dandurand, J.L., 1997 An experimental study of kaolinite dissolution and precipitation kinetics as a function of chemical affinity and solution composition at 150°C, 40 bars, and pH 2, 6.8, and 7.8 Geochimica et Cosmochimica Acta 61 51655186.CrossRefGoogle Scholar
Feng, X. Baojie, Z. and Chery, L., 2008 Effects of low temperature on aluminum (III) hydrolysis: Theoretical and experimental studies Journal of Environmental Sciences 20 907914.Google Scholar
Huertas, F.J. Chou, L. and Wollast, R., 1998 Mechanism of kaolinite dissolution at room temperature and pressure: part I Surface speciation. Geochimica et Cosmochimica Acta 63 417431.CrossRefGoogle Scholar
Huertas, F.J. Chou, L. and Wollast, R., 1999 Mechanism of kaolinite dissolution at room temperature and pressure: part II Kinetic study. Geochimica et Cosmochimica Acta 63 32613275.CrossRefGoogle Scholar
Hsu, P.H., Dixon, J.B. and Weed, S.B., 1989 Aluminum hydroxides and oxyhydroxides Minerals in Soil Environments 2nd Ed. Madison, Wisconsin Soil Science Society of America 331378.Google Scholar
Johnson, S.B. Franks, G.V. Scales, P.J. Boger, D.V. and Healy, T.W., 2000 Surface chemistry-rheology relationships in concentrated mineral suspensions International Journal of Mineral Processing 58 267304.CrossRefGoogle Scholar
Konta, J., 1995 Clay and man: clay raw materials in the service of man Applied Clay Science 10 275335.CrossRefGoogle Scholar
Lagaly, G., Bergaya, F. Theng, B.K.G. and Lagaly, G., 2006 Colloid clay science Handbook of Clay Science Amsterdam Elsevier 141245.CrossRefGoogle Scholar
Loginov, M. Larue, O. Lebovka, N. and Vorobiev, E., 2008 Fluidity of highly concentrated kaolin suspensions: influence of particle concentration and presence of dispersant Colloids and Surfaces A: Physicochemical and Engineering Aspects 325 6471.CrossRefGoogle Scholar
Mark, M., 2011 The dispersive effect of sodium silicate on kaolinite particles in process water: Implications for iron ore processing Clays and Clay Minerals 59 233239.Google Scholar
Moan, M. Aubry, T. and Bossard, F., 2003 Nonlinear behavior of very concentrated suspensions of plate-like kaolin particles in shear flow Journal of Rheology 47 14931504.CrossRefGoogle Scholar
Murray, H.H. and Kogelb, J.E., 2005 Engineered clay products for the paper industry Applied Clay Science 29 199206.CrossRefGoogle Scholar
Nagy, K.L. Blum, A.E. and Lasaga, A.C., 1991 Dissolution and precipitation kinetics of kaolinite at 80 degrees C and pH 3; the dependence on solution saturation state American Journal of Science 291 649686.CrossRefGoogle Scholar
Penner, D. and Lagaly, G., 2001 Influence of anions on the rheological properties of clay mineral dispersions Applied Clay Science 19 131142.CrossRefGoogle Scholar
Solomon, D.H. and Hawthorne, D.G., 1983 Chemistry of Pigments and Fillers New York Wiley 309.Google Scholar
Stucki, J.W. Goodman, B.A. and Schwertmann, U., 1988 Iron in Soils and Clay Minerals Dordrecht, Holland D. Reidel Publishing Company 476.Google Scholar
Wieland, E. and Stumm, W., 1992 Dissolution kinetics of kaolinite in acidic aqueous solutions at 25°C Geochimica et Cosmochimica Acta 56 33393355.CrossRefGoogle Scholar
Xie, Z. and Walther, J.V., 1992 Incongruent dissolution and surface area of kaolinite Geochimica et Cosmochimica Acta 56 33573363.CrossRefGoogle Scholar
Yang, L. and Steefel, C.I., 2008 Kaolinite dissolution and precipitation kinetics at 22°C and pH 4 Geochimica et Cosmochimica Acta 72 99116.CrossRefGoogle Scholar
Yuan, J. Garforth, W.L. and Pructt, R.J., 1998 Influence of dispersants on the solubility of calcined kaolin Applied Clay Science 13 137147.CrossRefGoogle Scholar
Zaman, A.A. and Mathur, S., 2004 Influence of dispersing agents and solution conditions on the solubility of crude kaolin Journal of Colloid and Interface Science 271 124130.CrossRefGoogle ScholarPubMed
Zaman, A.A. Tsuchiya, R. and Moudgil, B.M., 2001 Adsorption of a low-molecular-weight polyacrylic acid on silica, alumina, and kaolin Journal of Colloid and Interface Science 256 7378.CrossRefGoogle Scholar
Zaman, A.A. Demir, F. and Finch, E., 2003 Effects of process variables and their interactions on solubility of metal ions from crude kaolin particles: results of a statistical design of experiments Applied Clay Science 22 237250.CrossRefGoogle Scholar