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Catalysis by montmorillonites

Published online by Cambridge University Press:  09 July 2018

J. M. Adams ,
T. V. Clapp  and
D. E. Clement
J. M. Adams
Affiliation:
Edward Davies Chemical Laboratories, University College of Wales, Aberystwyth, Dyfed SY23 1NE
T. V. Clapp
Affiliation:
Edward Davies Chemical Laboratories, University College of Wales, Aberystwyth, Dyfed SY23 1NE
D. E. Clement
Affiliation:
Edward Davies Chemical Laboratories, University College of Wales, Aberystwyth, Dyfed SY23 1NE
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Abstract

A preliminary set of ‘rules’ for acid-catalysis by ion-exchanged montmorillonites has been derived from the reaction of alkenes, alcohols and alicyclic acids over such catalysts. It has been shown that: 1. Cr(III) and Fe(III) are the most active interlayer cations. Although Al is also active, the exact procedures used for the ion-exchange and washing steps appear to be critical for giving catalysts of reproducible activity. 2. Below 100°C, the reactions proceed provided they involve tertiary or allylic carbocation intermediates, whereas at 150–180°C reactions involving primary and secondary carbocations are possible. 3. Reactions of carbocations with unsaturated hydrocarbons take place overwhelmingly in the interlayer region of the clay, where the hydrocarbon double bond can be effectively polarized. Reactions of carbocations with polar, oxygenated, species can take place on the surface of the clay particles as well as in the interlayer space. 4. When the acid-catalysed reactions are performed in the liquid phase and involve tertiary carbocations, the most suitable solvents are those which provide miscibility; 1,4-dioxan is especially good. However, when more acid conditions are required for the formation of primary and secondary carbocations a non-polar solvent is more efficacious.

Type
Research Article
Information
Clay Minerals , Volume 18 , Issue 4 , December 1983 , pp. 411 - 421
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1983

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References

Adams, J.M., Ballantine, J.A., Graham, S.H., Laub, R.J., Purnell, J.H., Reid, P.I., Shaman, W.Y.M. & Thomas, J.M. (1978) Organic synthesis using sheet silicate intercalates: low temperature conversion of olefin to secondary ether. Angew. Chemie Int. Ed. 17, 282283.CrossRefGoogle Scholar
Adams, J.M., Ballantine, J.A., Graham, S.H., Laub, R.J., Purnell, J.H., Reid, P.I., Shaman, W.Y.M. & Thomas, J.M. (1979) Selective chemical conversions using sheet silicate intercalates: low temperature addition of water to 1-alkenes. J. Calai. 58, 239252.Google Scholar
Adams, J.M., Bylina, A. & Graham, S.H. (1981a) Shape selectivity in low-temperature reactions of C6-alkenes catalysed by a Cunexchanged montmorillonite. Clay Miner. 16, 325332.Google Scholar
Adams, J.M., Clement, D.E. & Graham, S.H. (1981b) low-temperature reactions of alcohols to form f-butyl ethers using clay catalysts. J. Chem. Res. S 254255.Google Scholar
Adams, J.M., Bylina, A. & Graham, S.H.. (1982a) Conversion of 1-hexene to di-2-hexyl ether using a Cu2+-smectite catalyst. J. Cala. 75, 190195.Google Scholar
Adams, J.M., Clement, D.E. & Graham, S.H. (1982b) Synthesis of methyl-t-butyl ether (MTBE) from methanol and isobutane using a clay catalyst. Clays Clay Miner. 30, 129134.Google Scholar
Adams, J.M., Davies, S.E., Graham, S.H. & Thomas, J.M. (1982C) Catalysed reactions of organic molecules at clay surfaces: ester breakdown, dimerization and lactonizations. J. Catal. 78, 197208.Google Scholar
Adams, J.M., Clement, D.E. & Graham, S.H. (1983) Reactions of alcohols with alkenes over an aluminium-exchanged montmorillonite. Clays Clay Miner. 31, 129136.Google Scholar
Anon, (1951) Table of Dielectric Constants of Pure Liquids. NBS Circular 514. NBS, Washington.Google Scholar
Ballantine, J.A., Davies, M., Purnell, J.H., Rayanakorn, M., Thomas, J.M. & Williams, K.J. (1981a) Chemical conversions using sheet silicates: facile ester synthesis by direct addition of acids to alkenes. J. C.S. Chem. Comm. 89.Google Scholar
Ballantine, J.A., Davies, M., Purnell, J.H., Rayanakorn, M., Thomas, J.M. & Williams, K.J. (1981b) Chemical conversions using sheet silicates: novel intermolecular dehydration of alcohols to ethers and polymers. J.C.S. Chem. Comm. 427428.Google Scholar
Bell, R.P. (1959) The Proton in Chemistry, p. 3. Methuen, London.Google Scholar
Bennett, H. & Reed, R.A. (1971) Chemical Methods in Silicate Analysis—A Handbook, pp. 7379. Academic Press, London.Google Scholar
Bylina, A., Adams, J.M., Graham, S.H. & Thomas, J.M. (1980) Chemical conversions using sheet silicates: a simple method for producing methyl t-butyl ether (MTBE). J. C.S. Chem. Comm. 10031004.Google Scholar
Clapp, T.V. (1981) Montmorillonites: catalytic activity with alk-1-enes. MSc Thesis, UCW, Aberystwyth.Google Scholar
Clement, D.E. (1982) Selective catalysis by layered silicates. PhD Thesis, UCW, Aberystwyth.Google Scholar
Csicsery, S.M. (1976) Shape selective catalysis. Pp. 680713 in: Zeolite Chemistry and Catalysis (Rabo, J. A., editor), ACS monograph 171, Washington.Google Scholar
Franz, W., Gunther, P. & Hofstadt, C.E. (1960) Catalysts on the basis of acid-activated montmorillonites. Proc. 5th World Petrol. Congr. 3, 123132.Google Scholar
Fripiat, J.J. & Cruz-Cumplido, M.I. (1974) Clays as catalysts for natural processes. Ann. Rev. Earth Planet. Sci. 2, 239256.Google Scholar
Hayden, P.L. & Rubin, A.J. (1974) Systematic investigation of the hydrolysis and precipitation of aluminium(III). Aqueous Environ. Chem. Met. 317381.Google Scholar
Lucatello, L.G. & Smith, G.E. (1972) Catalytic preparation of o-alkylatedphenols. UK Patent 1 265 152.Google Scholar
Mathers, A.C., Weed, S.B. & Coleman, N.T. (1956) The effect of acid and heat treatment on montmorillonite. Clays Clay Miner. 3, 403413.CrossRefGoogle Scholar
Mortland, M.M. (1968) Protonation of compounds at clay mineral surfaces. Trans. 9th Int. Congr. Soil Sci. 691699.Google Scholar
Mortland, M.M. & Mellor, J.L. (1954) Conductometric titration of soils for cation exchange capacity. Proc. Soil Sci. Soc. Am. 18, 363.Google Scholar
Mortland, M.M. & Raman, K.V. (1968) Surface acidity of smectites in relation to hydration, exchangeable cation and structure. Clays Clay Miner. 16, 393398.Google Scholar
Pinnavaia, T.J., Raythatha, R., Guo-Shuh Lee, J., Halloran, L.J. & Hoffman, J.F. (1979) Intercalation of catalytically active metal complexes in mica-type silicates. Rhodium hydrogenation catalysts. J. Am. Chem. Soc. 68916897.Google Scholar
Reid, P.I. (1978) Some physical and chemical aspects of sheet silicates. PhD Thesis, UCW, Aberystwyth.Google Scholar
Russell, J.D. & Farmer, V.C. (1964) Infrared spectroscopic study of the dehydration of montmorillonite and saponite. Clay Miner. Bull. 5, 443–364.Google Scholar
Ryland, L.B., Tamele, M.W. & Wilson, J.N. (1960) Cracking catalysts. Pp. 1-91 in: Catalysis (P. H. Emmett, editor), Reinbold, New York.Google Scholar
Weiss, A. (1981) Replication and evolution in inorganic systems. Angew. Chem. Int. Ed. 20, 850860.Google Scholar
Wiseman, P.(1979) An Introduction to Industrial Organic Chemistry, pp. 209214. Applied Science Publishers, London.Google Scholar