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Microstructural and porosimetry analysis of Ag-TiO2 intercalated kaolin and diatomite as nanocomposite ceramic materials

Published online by Cambridge University Press:  22 January 2019

Emmanuel Ajenifuja ,
Abimbola P.I. Popoola ,
Kabir O. Oyedotun  and
Olawale Popoola
Emmanuel Ajenifuja*
Affiliation:
Department of Chemical, Metallurgical and Materials Engineering, Tshwane University of Technology, Pretoria, South Africa Center for Energy and Electric Power, Tshwane University of Technology, Pretoria, South Africa
Abimbola P.I. Popoola
Affiliation:
Department of Chemical, Metallurgical and Materials Engineering, Tshwane University of Technology, Pretoria, South Africa
Kabir O. Oyedotun
Affiliation:
Department of Physics and Engineering Physics, Obafemi Awolowo University, Ile-Ife, Nigeria
Olawale Popoola
Affiliation:
Center for Energy and Electric Power, Tshwane University of Technology, Pretoria, South Africa
*
*E-mail: [email protected]
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Abstract

Kaolin and diatomite are abundant and widely available geological materials that may immobilize or stabilize functional chemical species on their surfaces for various applications. Acid-treated kaolin and diatomite were intercalated with photocatalyst Ag-TiO2 nanoparticles using the sol–gel technique to prepare nanocomposite ceramic materials. The nanocomposites were sintered between 900°C and 1000°C to induce thermal reactions and to enhance nanoparticle–substrate attachment. Chemical and thermal characterizations of the acid-treated materials and intercalated nanocomposites were performed with energy-dispersive X-ray (EDX) analysis and differential scanning calorimetry (DSC), respectively. The Brunauer–Emmett–Teller (BET)-specific surface area and scanning electron microscopy (SEM) were employed for physical and microstructural characterization of the nanocomposites, respectively. Morphological studies revealed a uniform distribution of Ag-TiO2 nanocrystallites in pores and on mineral particle surfaces. The BET analysis showed remarkable surface and grain modification by sintering. Decreases in the BET-specific surface area were observed for the sintered ceramic nanocomposite, Ag-TiO2-kaolin (20.244 to 5.446 m2/g) and Ag-TiO2-diatomite (19.582 to 10.148 m2/g).

Keywords

kaolindiatomiteBET-specific surface areasol–gelceramicsadsorbents
Type
Article
Information
Clay Minerals , Volume 53 , Issue 4 , December 2018 , pp. 665 - 674
Copyright
Copyright © Mineralogical Society of Great Britain and Ireland 2018 

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Footnotes

Associate Editor: M. Pospišíl

References

REFERENCES

Ajenifuja, E., Ajao, J.A. & Ajayi, E.O. (2017a) Adsorption isotherm studies of Cu (II) and Co (II) in high concentration aqueous solutions on photocatalytically modified diatomaceous ceramic adsorbents. Applied Water Science, 7, 37933801.Google Scholar
Ajenifuja, E., Ajao, J.A. & Ajayi, E.O. (2017b) Equilibrium adsorption isotherm studies of Cu (II) and Co (II) in high concentration aqueous solutions on Ag-TiO2-modified kaolinite ceramic adsorbents. Applied Water Science, 7, 22792286.Google Scholar
Alexandre, M. & Dubois, P. (2000) Polymer-layered silicate nanocomposites: preparation, properties and uses of a new class of materials. Materials Science Engineering, 28, 163.Google Scholar
Bakhsh, N., Khalid, F.A. & Hakeem, A.S. (2014) Effect of sintering temperature on densification and mechanical properties of pressureless sintered CNT–alumina nanocomposites. IOP Conference Series: Materials Science and Engineering, 60, 012059.Google Scholar
Bellotto, M., Gualtieri, A., Artioli, G. & Clark, S.M. (1995) Kinetic study of the kaolinite-mullite reaction sequence. Part I: kaolinite dehydroxylation. Physics and Chemistry of Minerals, 22, 207214.Google Scholar
Bergaya, F., Theng, B.K. & Lagaly, G. (2006) Handbook of Clay Science (1st edition). Elsevier, Amsterdam, The Netherlands.Google Scholar
Burg, T., Bak, T., Nowotny, J., Sheppard, L., Sorrell, C.C. & Vance, E.R. (2007) Effect of sintering on microstructure of TiO2 ceramics. Advances in Applied Ceramics, 106, 5762.Google Scholar
Caratto, V., Aliakbarian, B., Casazza, A.A., Setti, L., Bernini, C., Perego, P. & Ferretti, M. (2013) Inactivation of Escherichia coli on anatase and rutile nanoparticles using UV and fluorescent light. Materials Research Bulletin, 48, 20952101.Google Scholar
Carp, O., Huisman, C.L. & Reller, A. (2004) Photoinduced reactivity of titanium dioxide. Progress in Solid State Chemistry, 32, 133177.Google Scholar
Carrado, K.A. (2004) Introduction: clay structure, surface acidity, and catalysis. Pp. 138 in: Handbook of Layered Materials, Part I (Auerbach, S., Carrado, K.A. & Dutta, P.K., editors). Marcel Dekker, New York, NY, USA.Google Scholar
Chong, M.N., Tneu, Z.Y., Poh, P.E., Jin, B. & Aryal, R. (2014) Synthesis, characterisation and application of TiO2–zeolite nanocomposites for the advanced treatment of industrial dye wastewater. Journal of the Taiwan Institute of Chemical Engineers, 2014, 19.Google Scholar
Deer, W.A., Howie, R.A. & Zussman, J. (1994) An Introduction to the Rock-Forming Minerals. Longman, Harlow, UK.Google Scholar
Defontaine, G., Barichard, A., Letaief, S., Feng, C., Matsuura, T. & Detellier, C. (2010) Nanoporous polymer–clay hybrid membranes for gas separation. Journal of Colloid and Interface Science, 343, 622627.Google Scholar
Du, W., Xu, Y. & Wang, Y. (2008) Photoinduced degradation of orange II on different iron (hydr)oxides in aqueous suspension: rate enhancement on addition of hydrogen peroxide, silver nitrate, and sodium fluoride. Langmuir, 24, 175181.Google Scholar
Elbokl, T.A. & Detellier, C. (2006) Aluminosilicate nanohybrid materials. Intercalation of polystyrene in kaolinite. Journal of the Physics and Chemistry of Solids, 67, 950955.Google Scholar
Elbokl, T.A. & Detellier, C. (2009) Kaolinite-poly(methacrylamide) intercalated nanocomposite via in situ polymerization. Canadian Journal of Chemistry, 87, 272279.Google Scholar
Faulde, M.K., Tisch, M. & Scharninghausen, J.J. (2006) Efficacy of modified diatomaceous earth on different cockroach species (Orthoptera, Blattellidae) and silverfish (Thysanura, Lepismatidae). Journal of Pest Science, 79, 155161.Google Scholar
Fernandez-Saavedra, R., Darder, M., Gomez-Aviles, A., Aranda, P. & Ruiz-Hitzky, E. (2008) Polymer–clay nanocomposites as precursors of nano structured carbon materials for electrochemical devices: templating effect of clays. Journal of Nanoscience and Nanotechnology, 8, 17411750.Google Scholar
Ferraz, E., Coroado, J., Silva, J., Gomes, C. & Rocha, F. (2011) Manufacture of ceramic bricks using recycled brewing spent kieselguhr. Materials and Manufacturing Processes, 26, 13191329.Google Scholar
Fields, P., Allen, S., Korunic, Z., McLaughlin, A. & Stathers, T. (2002) Standardized testing for diatomaceous earth. Pp. 779784 in: Proceedings of the Eighth International Working Conference of Stored-Product Protection, York, UK. EurekaMag, York, UK.Google Scholar
Gómez-Romero, P. & Sanchez, C. (2004) Functional Hybrid Materials. Wiley-VCH, Weinheim, Germany.Google Scholar
Greenwood, N.N. & Earnshaw, A. (1984) Chemistry of the Elements. Pergamon Press, Oxford, UK.Google Scholar
Hathway, T. & Jenks, W.S. (2008) Effects of sintering of TiO2 particles on the mechanisms of photocatalytic degradation of organic molecules in water. Journal of Photochemistry and Photobiology A: Chemistry, 200, 216224.Google Scholar
Hoffmann, M.R., Martin, S.T., Choi, W. & Bahnemann, D.W. (1995) Environmental applications of semiconductor photocatalysis. Chemistry Reviews, 95, 6996.Google Scholar
Hubbard, A.T. (2002). Encyclopedia of Surface and Colloid Science. Taylor & Francis, Abingdon, UK.Google Scholar
Huertas, F.J., Fiore, S., Huertas, F. & Linares, J. (1999) Experimental study of the hydrothermal formation of kaolinite. Chemical Geology, 156, 171190.Google Scholar
Jiang, W., Mashayekhi, H. & Xing, B. (2009) Bacterial toxicity comparison between nano and micro-scaled oxide particles. Environmental Pollution, 157, 16191625.Google Scholar
Kay, A., Cesar, I. & Grätzel, M. (2006) New benchmark for water photooxidation by nanostructured alpha-Fe2O3 films. Journal of the American Chemical Society, 128, 1571415721.Google Scholar
Komadel, P. (1999) Structure and chemical characteristics of modified clays. Pp. 318 in: Natural Microporous Materials in Environmental Technology (Misaelides, P., Macasek, F., Pinnavaia, T.J. & Collela, C., editors). Kluwer Academic, Dordrecht, The Netherlands.Google Scholar
Kruk, M. & Jaroniec, M. (2001) Gas adsorption characterization of ordered organic–inorganic nanocomposite materials. Chemistry of Materials, 13, 31693183.Google Scholar
Leiviskä, T., Gehör, S., Eijärvi, E., Sarpola, A. & Tanskanen, J. (2012) Characteristics and potential applications of coarse clay fractions from Puolanka, Finland. Central European Journal of Engineering, 2, 239247.Google Scholar
Letaief, S., Aranda, P., Fernandez-Saavedra, R., Margeson, J.C., Detellier, C. & Ruiz-Hitzky, E. (2008) Poly(3, 4-ethylenedioxythiophene)–clay nanocomposites. Journal of Materials Chemistry, 18, 22272233.Google Scholar
Li, S.Q., Zhu, R.R., Zhu, H., Xue, M., Sun, X.Y., Yao, S.D. & Wang, S.L. (2008) Nanotoxicity of TiO2 nanoparticles to erythrocyte in vitro. Food Chemistry and Toxicology, 46, 36263631.Google Scholar
Li, S., Wu, Q., Cui, C., Lu, G., Zhang, C. & Yan, Z. (2013) Preparation of TiO2/Al–MCM-41 mesoporous materials from coal-series kaolin and photodegradation of methyl orange. Materials Science – Poland, 31, 372377.Google Scholar
Mokaya, R., Jones, W., Davies, M.E. & Whittle, M.E. (1993) Preparation of alumina-pillared acid-activated clays and their use as chlorophyll adsorbents. Journal of Materials Chemistry, 3, 381387.Google Scholar
Ozcan, A.S. & Ozcan, A. (2004) Adsorption of acid dyes from aqueous solutions onto acid-activated bentonite. Journal of Colloid and Interface Science, 276, 3946.Google Scholar
Pinnavaia, T.J. & Beall, G.W. (2000) Polymer–Clay Nanocomposites. Wiley, Oxford, UK.Google Scholar
Plachá, D., Martynková, G.S. & Rümmeli, M.H. (2008) Preparation of organovermiculites using HDTMA: structure and sorptive properties using naphthalene. Journal of Colloid and Interface Science, 327, 341347.Google Scholar
Plachá, D., Rosenbergová, K., Slabotínsky, J., Kutláková, K.M., Studentová, S. & Martynková, G.S. (2014) Modified clay minerals efficiency against chemical and biological warfare agents for civil human protection. Journal of Hazardous Materials, 271, 6572.Google Scholar
Ratke, L. & Voorhees, P.W. (2002) Growth and Coarsening: Ostwald Ripening in Material Processing. Springer Science & Business Media, Berlin, Germany.Google Scholar
Ray, S. & Okamoto, M. (2003) Polymer/layered silicate nanocomposites: a review from preparation to processing. Progress in Polymer Science, 28, 15391541.Google Scholar
Rouquerol, F., Rouquerol, J. & Sing, K. (1999) Adsorption by Powders and Porous Solids. Academic Press, London, UK.Google Scholar
Ruiz-Hitzky, E. & Van Meerbek, A. (2006) Polymer–clay nanocomposites. Pp. 113142 in: Handbook of Clay Science (Bergaya, F., Theng, B. & Lagaly, G., editors). Elsevier, Amsterdam, The Netherlands.Google Scholar
Samyn, P., Schoukens, G., & Stanssens, D. (2015) Kaolinite nanocomposite platelets synthesized by intercalation and imidization of poly(styrene-co-maleic anhydride). Materials, 8, 43634388.Google Scholar
Sing, K.S., Everett, D.H., Haul, R.A., Moscou, L., Pierotti, R.A., Rouquerol, J. & Siemieniewska, T. (1985) Physical and biophysical chemistry division commission on colloid and surface chemistry including catalysis. Pure and Applied Chemistry, 57, 603619.Google Scholar
Szabó, T., Németh, J. & Dékány, I. (2003) Zinc oxide nanoparticles incorporated in ultrathin layer silicate films and their photocatalytic properties. Colloids and Surfaces A, 230, 2335.Google Scholar
Tomura, S., Shibasaki, Y., Mizuta, H. & Kitamura, M. (1985) Growth conditions and genesis of spherical and platy kaolinite. Clays and Clay Minerals, 33, 200206.Google Scholar
Tsai, W.-T., Lai, C.-W. & Hsien, K.-J. (2006) Characterization and adsorption properties of diatomaceous earth modified by hydrofluoric acid etching. Journal of Colloid and Interface Science, 297, 749754.Google Scholar
Tunney, J.J. & Detellier, C. (1996) Aluminosilicate nanocomposite materials: poly(ethylene glycol)–kaolinite intercalates. Chemistry of Materials, 8, 927935.Google Scholar
Vicente Rodriguez, M.A., Suarez Barrios, M., Lopez Gonzalez, J.D. & Banares Munoz, M.A. (1994) Acid activation of a ferrous saponite (griffithite): physicochemical characterization and surface area of the products obtained. Clays and Clay Minerals, 42, 724730.Google Scholar
Vimonses, V., Chong, M.N. & Jin, B. (2010) Evaluation of the physical properties and photodegradation ability of titania nanocrystalline impregnated onto modified kaolin. Microporous Mesoporous Materials, 132, 201209.Google Scholar
Wang, Y., Du, W. & Xu, Y. (2009) Effect of sintering temperature on the photocatalytic activities and stabilities of hematite and silica-dispersed hematite particles for organic degradation in aqueous suspensions. Langmuir, 25, 28952899.Google Scholar
Warheit, D.B., Hoke, R.A., Finlay, C., Maria Donner, E., Reed, K.L. & Sayes, C.M. (2007) Development of a base set of toxicity tests using ultrafine TiO2 particles as a component of nanoparticle risk management. Toxicology Letters, 171, 99110.Google Scholar