Chemistry, Physics and Technology of Surface

ISSN 2518-1238 (Online), ISSN 2079-1704 (Print)

The mechanism of thermolysis of chromium (III) acetylacetonate Cr(acac)₃ molecules adsorbed on silica and alumina surfaces has been studied by temperature programmed desorption mass spectrometry. It has been found that the thermolysis of Cr(acac)3 on silica surface occurs due to substitution of the support hydroxyl groups for hydrogen bonded ligands and dimerization of free acetylacetonate ligands by migration of hydrogen atom of methyl group to oxygen atom of enol and carbonyl groups followed by decomposition of dimeric macroligands and single acetylacetonate ligands with elimination of small molecules. The thermolysis of Cr(acac)₃ on alumina surface occurs due to dimerization of free acetylacetonate ligands via migration of hydrogen atom of methyl group to oxygen atom of carbonyl group followed by decomposition of dimeric macroligands and single acetylacetonate ligands with elimination of small molecules.

Weckhuysen B.M., Rao R.R., Pelgrims J. et al. Synthesis, spectroscopy and catalysis of [Cr(acac)3] complex grafted onto MCM-41 materials: formation of polyethylene nanofibres within mesoporous crystalline aluminosilicates // Chem. Eur. J. – 2000. – V. 6. – P. 2960–2970.

Calleja G., Aguado J., Carrero A., Moreno J. Chromium supported onto swelled Al-MCM-41 materials: a promising catalysts family for ethylene polymerization // Catal. Commun. – 2005. – V. 6. – P. 153–157.

Rao R.R., Weckhuysen B.M., Schoonheydt R.A. Ethylene polymerization over chromium complexes grafted onto MCM-41 materials // Chem. Commun. – 1999. – P. 445–446.

Köhler S., Reiche M., Frobel C., Baerns M. Preparation of catalysts by chemical vapor-phase deposition and decomposition on support materials in a fluidized-bed reactor // Stud. Surf. Sci. Catal. – 1995. – V. 91. – P. 1009–1016.

Kytökivi A., Jacobs J.-P., Hakuli A. et al. Surface characterization and activity of chromia/alumina catalysts prepared by atomic layer epitaxy // J. Catal. – 1996. – V. 162. – P. 190–197.

Puurunen R.L., Airaksinen S.M.K., Krause A.O.I. Chromium(III) supported on aluminum-nitride-surfaced alumina: characteristics and dehydrogenation activity // J. Catal. – 2003. – V. 213. – P. 281–290.

Airaksinen S.M.K., Krause A.O.I. Effect of catalyst prereduction on the dehydrogenation of isobutane over chromia/alumina // Ind. Eng. Chem. Res. – 2005. – V. 44. – P. 3862–3868.

Karinen R., Airaksinen S., Kiviranta P. et al. Application of microreactors in the dehydrogenation of isobutane // Top. Catal. – 2011. – V. 54. – P. 1206–1212.

Haukka S., Lakomaa E.-L., Suntola T. Chemisorption of chromium acetylacetonate on porous high surface area silica // Appl. Surf. Sci. – 1994. – V. 75. – P. 220–227.

Ruddick V. J., Dyer P. W., Bell G. et al. Mechanistic study of the calcination of supported chromium (III) precursors for ethene polymerization catalysts // J. Phys. Chem. – 1996. – V. 100. – P. 11062–11066.

Babich I. V., Plyuto Yu. V., Van der Voort P., Vansant E. F. Thermal transformations of chromium acetylacetonate on silica surface // J. Colloid Interf. Sci. – 1997. – V. 189. – P. 144–150.

Hakuli A., Kytökivi A. Binding of chromium acetylacetonate on a silica support // Phys. Chem. Chem. Phys. – 1999. – V. 1. – P. 1607–1613.

Babich I.V., Plyuto Yu.V., Van der Voort P., Vansant E.F. Gas-phase deposition and thermal transformations of Cr(acac)3 on the surface of alumina supports // J. Chem. Soc., Faraday Trans. – 1997. – V. 93. – Р. 3191–3196.

Davydenko L., Mischanchuk B., Pokrovskiy V. et al. TPD-MS and IR studies of Cr(acac)3 binding upon CVD at silica and alumina surfaces // Chem. Vap. Dep. – 2011. – V. 17. – P. 123–127.

Schmidt M.W. Baldridge K.K., Boatz J.A. et al. General atomic and molecular electronic structure system: Review // J. Comput. Chem. – 1993. – V. 14, N 11. – P.1347–1363.

Bykov A.F., Turgambaeva A.E., Igumenov I.K., Semyannikov P.P. Mass spectrometric study of thermolysis mechanism of metal acetylacetonates vapour // Journal de Physique IV, Colloque C5, supplement au Journal de Physique II. – 1995. – V. 5. – P. 191–197.