Zirconium hydrocarbyl chemisorption on sulfated metal oxides: new supports, chemisorption pathways, and implications for catalysis.

Christopher P Nicholas, Tobin J Marks

Index: Langmuir 20(22) , 9456-62, (2004)

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Abstract

The sulfated metal oxides (SMOs) sulfated stannia (SnS), sulfated iron oxide (FeS), and sulfated titanium dioxide (TiS) have been synthesized and examined as support materials/cocatalysts/activators for molecule-based olefin polymerization and hydrogenation catalysis. (13)C CPMAS NMR spectroscopic analysis of Cp(2)Zr((13)CH(3))(2)/SMO chemisorption shows that cationic zirconocenium species are formed along with varying amounts of catalytically inactive micro-oxo (Cp(2)Zr(CH(3))O-surface) species, depending on the support material. Ethylene polymerization data with the supported catalysts show that polymerization activity is dependent on both precursor ligation [Zr(CH(2)Ph)(4) > (Me(5)Cp)ZrMe(3)] and the nature of the support (SnS > FeS > TiS). Poisoning studies were performed in conjunction with ethylene polymerization, mediated by (Me(5)Cp)ZrMe(3) supported on each SMO, and reveal that, for (Me(5)Cp)ZrMe(3)/SnS, 61 +/- 5% of the Zr sites are catalytically significant, while, for (Me(5)Cp)ZrMe(3)/FeS, this quantity is 22 +/- 2%, and for (Me(5)Cp)ZrMe(3)/TiS, 63 +/- 9%. These catalysts are also active for benzene hydrogenation and are separable from liquid-phase products using physical or, in the case of FeS, magnetic techniques.