Authors: Wanyu Mao, Hongfang Ma, Haitao Zhang, WeixinQian, Weiyong Ying

Abstract:

The nature of adsorbed species on catalytic surface over an industrial precipitated iron-based high temperature catalyst during FTS was investigated by in-situ DRIFTS and chemical trapping. The formulation of the mechanism of oxygenates formation and key intermediates were also discussed. Numerous oxygenated precursors and crucial intermediates were found by in-situ DRIFTS, such as surface acetate, acetyl and methoxide. The results showed that adsorbed molecules on surface such as methanol or acetaldehyde could react with basic sites such as lattice oxygen or free surface hydroxyls. Adsorbed molecules also had reactivity of oxidizing. Moreover, acetyl as a key intermediate for oxygenates was observed by investigation of CH3OH + CO and CH3I + CO + H2. Based on the nature of surface properties, the mechanism of oxygenates formation on precipitated iron-based high temperature catalyst was discussed.

Keywords: Iron-based catalysts, intermediates, oxygenates, in-situ DRIFTS, chemical trapping.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1087522

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1506

References:

[1] M.E. Dry, “Catalysis-Science and Technology”, vol. 1, Anderson and Boudart, Ed. New York: Springer Verlag, 1981, pp. 159.
[2] A. Takeuchi, J.R. katzer, “Mechanism of methanol formation”, J. Phys. Chem., vol. 85, pp. 937-939, Feb. 1981.
[3] D.G. Castner, R.L. Blackadar, G.A. Somorjai, “CO hydrogenation over clean and oxidized rhodium foil and single crystal catalysts. Correlations of catalyst activity, selectivity, and surface composition”, J. Catal., vol. 66, pp. 257-266, Dec. 1980.
[4] M. Ichikawa, T. Fukushima, “Mechanism of syngas conversion into C2-oxygenates such as ethanol catalysed on a SiO2-supported Rh-Ti catalyst”, J. Chem. Soc. Chem. Comm., vol. 1985, pp. 321-323, 1985.
[5] M. Pijolat, V. Perrichon, “Synthesis of alcohols from CO and H2 on a Fe/A12O3 catalyst at 8-30 bars pressure”, Appl. Catal., vol. 13, pp. 321-333, Jan. 1985.
[6] A. Kiennemann, C. Diagne, J.P. Hindermann P. Chaumette, Ph. Courty, “Higher alcohols synthesis from CO+2H2 on cobalt-copper catalyst: Use of probe molecules and chemical trapping in the study of the reaction mechanism”, Appl. Catal., vol. 53, pp. 197-216, Sep. 1989.
[7] J.L. Davis, M.A. Barteau, “Spectroscopic identification of alkoxide, aldehyde, and acyl intermediates in alcohol decomposition on Pd(111)”, Surf. Sci., vol. 235, pp. 235-248, Sep. 1990.
[8] C. Schild, A. Wokaun, A. Baiker, “On the mechanism of CO and CO2 hydrogenation reactions on zirconia-supported catalysts: a diffuse reflectance FTIR study: Part II. Surface species on copper/zirconia catalysts: implications for methanol synthesis selectivity”, J. Mol. Catal., vol. 63, pp. 243-254, Dec. 1990.
[9] R.G. Greenler, “An infrared investigation of xanthate adsorption by lead sulfide”, J. Chem. Phys., vol. 66, pp. 879-883, May 1962.
[10] M. Domok, M. Toth, J. Rasko, A. Erdohelyi, “Adsorption and reactions of ethanol and ethanol-water mixture on alumina-supported Pt catalysts”, Appl. Catal. B, vol. 69, pp. 262-272, Jan. 2007.
[11] V. Zamboni, G. Zerbi, “Vibrational spectrum of a new crystalline modification of polyoxymethylene”, J. Polym. Sci., vol. 7, pp. 153-161, Mar. 1964.
[12] Y. Ei-Sayed, T J. Bandosz, “A Study of Acetaldehyde Adsorption on Activated Carbons”, J. Coll. Interf. Sci., vol. 242, pp. 44-51, Oct. 2001.
[13] Y. He, J.H. Chin, “In-Situ DRIFTS Study on Catalytic Oxidation of Formaldehyde over Pt/TiO2 under Mild Conditions”, Chin. J. Catal., vol. 31, pp. 171-175, Feb. 2010.
[14] G. Busca, V. Lorenzelli, “Infrared study of methanol, formaldehyde, and formic acid adsorbed on hematite”, J. Catal., vol. 66, pp. 155-161, Nov. 1980.
[15] A.B. Anton, J.E. Parmeter, W.H. Weinberg, “Adsorption of formaldehyde on the Ru(001) and Ru(001)-p(2 .times. 2)O surfaces”, J. Am. Chem. Soc., vol. 108, pp. 1823-1833, April 1986.
[16] D. Demri, L. Chateau, J.P. Hindermann, A. Kiennemann, M.M. Bettahar, “C1-oxygenated molecules adsorbed on rhodium containing catalysts. Identification of a formyl species”, J. Mol. Catal., vol. 104, pp. 237-249, Jan. 1996.
[17] H. Idriss, J.P. Hindermann, R. Kieffer, “Characterization of dioxymethylene species over Cu-Zn catalysts”, J. Mol. Catal., vol. 42(2), pp. 205-213, Oct. 1987.
[18] W.Y. Ying, F.H. Cao, D,Y, Fang, “Major products and technology in C1 Chemical industry”, vol. 1, Beijing: Chemical Industry Press, 2004, pp. 78.
[19] J.C. Lavalley, J. Saussey, J. Lamotte, “Infrared study of carbon monoxide hydrogenation over rhodium/ceria and rhodium/silica catalysts”, J. Phys. Chem., vol. 94, pp. 5941-5947, July 1990.
[20] A.B. Mark, S.C. Steven, A.H. Scott, “Dynamic and kinetic modeling of isotopic transient responses for CO insertion on Rh and Mn–Rh catalysts”, Catal. Today, vol. 44, pp. 151-163, Sep. 1998.
[21] D. Forster “Mechanistic Pathways in the Catalytic Carbonylation of Methanol by Rhodium and Iridium Complexes”, Adv. Organomet. Chem., vol. 17, pp. 255-267, 1979.
[22] L. Chateau, J.P. Hindermann, A. Kiennemann, E. Tempesti. “On the mechanism of carbonylation in acetic acid and higher acid synthesis from methanol and syngas mixtures on supported rhodium catalysts”, J. Mol. Catal., vol. 107, pp. 367-378, May 1996.
[23] J.C. LAVALLEY, J. SAUSSEY, T. RAIS “Infrared study of the interaction between CO and H2 on ZnO: Mechanism and sites of formation of formyl species”, J. Mol. Catal., vol. 17(2-3), pp. 289-298, Nov.-Dec. 1982.
[24] J. Saussey, J.C. Lavalley, T. Rais, A. Chakor-Alami, J.P. Hindermann, A. Kiennemann, “The formation of formyl species from CO + H2 on ZnO: evidence and comparative study using IR spectroscopy and chemical trapping”, J. Mol. Catal., vol. 26(1), pp. 159-163, Feb. 1984.
[25] O. Johnston, R. Joyner, “Structure-Function Relationships in Heterogeneous Catalysis: the Embedded Surface Molecule Approach and Its Applications”, Stud. Surf. Sci. Catal., vol. 75, pp. 165-180, July 1993.
[26] G.A. Vedage, R.G. Herman, K. Klier, “Chemical trapping of surface intermediates in methanol synthesis by amines”, J. Catal., vol. 95(2), pp. 423-434, Oct. 1985.