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Preparation, characterization and catalytic properties of yttrium-zirconium-pillared montmorillonite and their application in supported Ce catalysts

Published online by Cambridge University Press:  02 January 2018

Bo Xue
Affiliation:
Institute of Catalysis, Zhejiang University, Hangzhou 310028 P.R. China
Hongmei Guo
Affiliation:
Institute of Catalysis, Zhejiang University, Hangzhou 310028 P.R. China
Lujie Liu
Affiliation:
Institute of Catalysis, Zhejiang University, Hangzhou 310028 P.R. China
Min Chen*
Affiliation:
Institute of Catalysis, Zhejiang University, Hangzhou 310028 P.R. China
*

Abstract

A new yttrium-zirconium-pillared montmorillonite (Y-Zr-MMT), was synthesized, characterized and used as a Ce catalyst support. The Y-Zr-MMT is a good support for dispersing cerium active sites and it is responsible for the high activity in the total oxidation of acetone, toluene and ethyl acetate. The Y-Zr-MMT shows greater advantages than the conventional alumina/cordierite honeycomb supports such as large specific surface area, lower cost and easier preparation. Catalytic tests demonstrated that Ce/Y-Zr-MMT (Ce loading 8.0%) was the most active, with the total oxidation of acetone, toluene and ethyl acetate being achieved at 220, 300 and 220°C, respectively. The catalyst displayed better activity for the oxidation of acetone and ethyl acetate than a conventional, supported Pd-catalyst under similar conditions. The special structure of the yttrium-doped zirconium-pillared montmorillonite can strengthen the interaction between the CeO2 and Zr-MMT support and improve the dispersion of the Ce particles, which enhances the catalytic activity for the oxidation of VOCs. The new catalyst, 8.0%Ce/Y-Zr-MMT, could be promising for industrial applications due to its high catalytic activity and low cost. The support and the catalysts were characterized by X-ray diffraction (XRD), transmission electron microscopy (TEM) and BET specific surface area measurements.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2015

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References

Ahmad, A., Hussain, S.T., Muhammad, B., Ali, N., Abbas, S.M. & Ali, Z. (2013) Zr-pillared montmorillonite supported cobalt nanoparticles for Fischer–Tropsch synthesis. Progress in Natural Science: Materials International, 23, 374381.CrossRefGoogle Scholar
Azalim, S., Brahmi, R., Agunaou, M., Beaurain, M., Giraudon, J.M. & Lamonier, J.F. (2013) Washcoating of cordierite honeycomb with Ce–Zr–Mn mixed oxides for VOC catalytic oxidation. Chemical Engineering Journal, 223, 536546.Google Scholar
Bineesh, K.V., Kim, M., Lee, G.H., Selvaraj, M. & Park, D.W. (2013) Catalytic performance of vanadiadoped alumina-pillared clay for selective oxidation of H2S. Applied Clay Science, 74, 127134.Google Scholar
Bineesh, K.V., Kim, S.Y., Jeremy, B.R. & Park, D.W. (2009) Synthesis, characterization and catalytic performance of vanadium-doped delaminated zirconia- pillared montmorillonite clay for the selective catalytic oxidation of hydrogen sulfide. Journal of Molecular Catalysis A: Chemical, 308, 150158.Google Scholar
Chang, K.C., Lai, M.C., Peng, C.W., Chen, Y.T., Yeh, J.M., Lin, C.L. & Yang, J.C. (2006) Comparative studies on the corrosion protection effect of DBSA-doped polyaniline prepared from in situ emulsion polymerization in the presence of hydrophilic Na+-MMT and organophilic organo-MMT clay platelets. Electrochimica Acta, 51, 56455653.Google Scholar
Chen, M., Fan, L.P., Qi, L.Y., Luo, X.Y., Zhou, R.X. & Zheng, X.M. (2009) The catalytic combustion of VOCs over copper catalysts supported on ceriummodified and zirconium-pillared montmorillonite. Catalysis Communications, 10, 838841.Google Scholar
Chuang, K.T., Davydov, A.A., Sanger, A.R. & Zhang, M.Q. (1997) Effect of fluorination of alumina support on activity of platinum catalysts for complete oxidation of benzene. Catalysis Letters, 49, 155161.Google Scholar
Colman-Lerner, J.E., Peluso, M.A., Sambeth, J.E. & Thomas, H.J. (2013) Volatile organic compound over bentonite-supported Pt,Mn and Pt/Mn monolithic catalysts. Reaction Kinetics Mechanisms and Catalysis, 108, 443458.Google Scholar
Craciun, R. (1998) Structure/activity correlation for unpromoted and CeO2-promoted MnO2/SiO2 catalysts. Catalysis Letters, 55, 2531.Google Scholar
Delimaris, D. & Ioannidis, Th. (2009) VOC oxidation over CuO–CeO2 catalysts prepared by a combustion method. Applied Catalysis B: Environmental, 89, 295302.CrossRefGoogle Scholar
Ding, Z., Kloprogge, J.T., Frost, R.L., Lu, G.Q. & Zhu, H.Y. (2001) Porous clays and pillared clays-based catalysts; Part 2: A review of the catalytic and molecular sieve applications. Journal of Porous Materials, 8, 273293.Google Scholar
Gandhe, A.R., Rebello, J.S., Figueiredo, J.L. & Fernandes, J.B. (2007) Manganese oxide OMS- 2 as an effective catalyst for total oxidation of ethyl acetate. Applied Catalysis B: Environmental, 72, 129135.Google Scholar
Gutierrez-Ortiz, J.I., Rivas, B.D., Lopez-Fonseca, R. & Gonzalez-Velasco, J.R. (2006) Catalytic purification of waste gases containing VOC mixtures with Ce/Zr solid solutions. Applied Catalysis B: Environmental, 65, 191200.Google Scholar
Hajjaji, W., Ganiyu, S.O., Tobaldi, D.M., Andrejkovicova, S., Pullar, R.C., Rocha, F. & Labrincha, J.A. (2013) Natural Portuguese clayey materials and derived TiO2-containing composites used for decoloring methylene blue (MB) and orange II (OII) solutions. Applied Clay Science, 83–84, 91–98.Google Scholar
Hao, Q.Q., Wang, G.W., Zhao, Y.H., Liu, Z.T. & Liu, Z.W. (2013) Fischer–Tropsch synthesis over cobalt/montmorillonite promoted with different interlayer cations. Fuel, 109, 3342.Google Scholar
He, C., Li, J.J., Li, P., Cheng, J., Hao, Z.P. & Xu, Z.P. (2010) Comprehensive investigation of Pd/ZSM– 5/MCM–48 composite catalysts with enhanced activity and stability for benzene oxidation. Applied Catalysis B: Environmental, 96, 466475.Google Scholar
Issaadi, R., Garin, F. & Chitour, C.E. (2001) Catalytic behaviour of combined palladium-acid catalysts: use of Al- and Zr-pillared montmorillonite as support: Part I. Reactivity of linear, branched and cyclic hexane hydrocarbons. Applied Catalysis A: General, 207, 323332.Google Scholar
Jarraya, I., Fourmentin, S., Benzina, M. & Bouaziz, S. (2010) VOC adsorption on raw and modified clay materials. Chemical Geology, 275, 18.Google Scholar
Li, D., Li, C.S. & Suzuki, K. (2013) Catalytic oxidation of VOCs over Al- and Fe-pillared montmorillonite. Applied Clay Science, 77–78, 5660.CrossRefGoogle Scholar
Li, N. & Gaillard, F. (2009) Catalytic combustion of toluene over electrochemically promoted Ag catalyst. Applied Catalysis B: Environmental, 88, 152159.Google Scholar
Li, W.B., Wang, J.X. & Gong, H. (2009) Catalytic combustion of VOCs on non-noble metal catalysts. Catalysis Today, 148, 8187.CrossRefGoogle Scholar
Liotta, L.F. (2010) Catalytic oxidation of volatile organic compounds on supported noble metals. Applied Catalysis B: Environmental, 100, 403412.CrossRefGoogle Scholar
Lu, C.Y., Wey, M.Y. & Chen, L.I. (2007) Application of polyol process to prepare AC-supported nanocatalyst for VOC oxidation. Applied Catalysis A: General, 325, 163174.Google Scholar
Morales-Torres, S., Maldonado-Hódar, F.J., Pérez-Cadenas, A.F. & Carrasco-Marín, F. (2010) Design of low-temperature Pt-carbon combustion catalysts for VOCs treatments. Journal of Hazardous Materials, 183, 814822.Google Scholar
Pakharukova, V.P., Moroz, E.M., Zyuzin, D.A., Zaikovskii, V.I., Tuzikov, F.V., Kosmambetova, G.R. & Strizhak, P.E. (2012) Structure characterization of nanocrystalline yttria-stabilized zirconia powders prepared via microwave-assisted synthesis. The Journal of Physical Chemistry, 116, 97629768.Google Scholar
Pande, G., Selvakumar, S., Batra, V.S., Gardoll, O. & Lamonier, J.F. (2012) Unburned carbon from bagasse fly ash as a support for a VOC oxidation catalyst. Catalysis Today, 190, 4753.Google Scholar
Papaefthimiou, P., Ioannides, T. & Verykios, X.E. (1999) VOC removal: investigation of ethyl acetate oxidation over supported Pt catalysts. Catalysis Today, 54, 8192.Google Scholar
Rivas, B.D., López-Fonseca, R., Jiménez-González, C. & Gutiérrez-Ortiz, J. (2011) Synthesis, characterisation and catalytic performance of nanocrystalline Co3O4 for gas-phase chlorinated VOC abatement. Journal of Catalysis, 281, 8897.Google Scholar
Ryu, C.Y. & Yeo, S.D. (2010) Vapor phase adsorption of trichloroethane using organically modified montmorillonite. Journal of Industrial and Engineering Chemistry, 16, 441447.Google Scholar
Santos, V.P., Carabineiro, S.A.C., Tavares, P.B., Pereira, M.F.R., Órfão, J.J.M. & Figueiredo, J.L.F. (2010) Oxidation of CO, ethanol and toluene over TiO2- supported noble metal catalysts. Applied Catalysis B: Environmental, 99, 198205.Google Scholar
Su, X.W., Jin, L.Y., Lu, J.Q. & Luo, M.F. (2009) Pd/Ce0.9Cu0.1O1.9–Y2O3 catalysts for catalytic combustion of toluene and ethyl acetate. Journal of Industrial and Engineering Chemistry, 15, 683686.Google Scholar
Trikittiwong, P., Sukpirom, N. & Chavasiri, W. (2013) Regioselective epoxide ring opening mediated by iron oxide-pillared clay. Journal of Molecular Catalysis A: Chemical, 378, 7681.Google Scholar
Tsou, J., Pinard, L., Magnoux, P., Figueiredo, J.L. & Guisnet, M. (2003) Catalytic oxidation of volatile organic compounds (VOCs): Oxidation of o-xylene over Pt/HBEA catalysts. Applied Catalysis B: Environmental, 46, 371379.Google Scholar
Wang, L.F., Tran, T.H., Vo, D.V., Sakurai, M. & Kameyama, H. (2008) Design of novel Pt-structured catalyst on anodic aluminium support for VOC’s catalytic combustion. Applied Catalysis A: General, 350, 150156.Google Scholar
Wu, J.C.S. & Chang, T.Y. (1998) VOC deep oxidation over Pt catalysts using hydrophobic supports. Catalysis Today, 44, 111118.Google Scholar
Yeh, J.M., Kuo, T.H., Huang, H.J., Chang, K.H., Chang, M.Y. & Yang, J.C. (2007) Preparation and characterization of poly(o-methoxyaniline)/Na+–MMT clay nanocomposite via emulsion polymerization: Electrochemical studies of corrosion protection. European Polymer Journal, 43, 16241634.Google Scholar
Yi, F.Y., Lin, X.D., Chen, S.X. & Wei, X.Q. (2009) Adsorption of VOC on modified activated carbon fiber. Journal of Porous Materials, 16, 521526.Google Scholar
Zaitan, H., Korrir, A., Chafik, T. & Bianchi, D. (2013) Evaluation of the potential of volatile organic compound (di-methyl benzene) removal using adsorption on natural minerals compared to commercial oxides. Journal of Hazardous Materials, 262, 365376.Google Scholar
Zhou, J.B., Wu, P.X., Dang, Z., Zhu, N.W., Li, P., Wu, J.H. & Wang, X.D. (2010) Polymeric Fe/Zr pillared montmorillonite for the removal of Cr(VI) from aqueous solutions. Chemical Engineering Journal, 162, 10351044.Google Scholar
Zhu, H.Q., Qin, Z.F., Shan, W.J., Shen, W.J. & Wang, J.G. (2004) Pd/CeO2–TiO2 catalyst for CO oxidation at low temperature: a TPR study with H2 and CO as reducing agents. Journal of Catalysis, 225, 267277.CrossRefGoogle Scholar
Zuo, S.F., Zhou, R.X. & Qi, C.Z. (2011) Synthesis and characterization of aluminium and Al/REE pillared clays and supported palladium catalysts for benzene oxidation. Journal of Rare Earths, 29, 5257.Google Scholar