The ethylene epoxidation cycle in a H2O2/H2O-loaded Ti zeolite has been simulated by a Car-Parrinello approach. Results indicate a process where the zeolitic framework is the active oxygen mediator. The dissociative chemisorption of H2O2 leads, via a transient Ti-hydroperoxo species, to H2O and a Ti-peroxo zeolite intermediate. Transfer of active oxygen to ethylene follows, giving the epoxide and recovering the catalyst. A thorough theoretical characterization indicates that the active oxidizing species is an asymmetric eta(2)-Ti-peroxo, absorbing in the visible range. The lability of the intermediate is found related to eta(2) <-> eta(1) interconversions of the Ti-peroxo structure. The interconversions, triggered by water molecules, could account for the experimentally found reduced catalytic activity in aged TS-1 catalysts. The results provide a microscopic picture of the reactivity and dehydration/aging processes of the catalyst fully consistent with experiments and highlight the fundamental role of the Lewis acid character of Ti in the formation, reactivity, and degradation of the active oxidizing species.

On the Role of Ti(IV) as a Lewis Acid in the Chemistry of Titanium Zeolites: Formation, Structure, Reactivity, and Aging of Ti-Peroxo Oxidizing Intermediates. A First Principles Study

TABACCHI, GLORIA;GAMBA, ALDO;FOIS, ETTORE SILVESTRO
2006-01-01

Abstract

The ethylene epoxidation cycle in a H2O2/H2O-loaded Ti zeolite has been simulated by a Car-Parrinello approach. Results indicate a process where the zeolitic framework is the active oxygen mediator. The dissociative chemisorption of H2O2 leads, via a transient Ti-hydroperoxo species, to H2O and a Ti-peroxo zeolite intermediate. Transfer of active oxygen to ethylene follows, giving the epoxide and recovering the catalyst. A thorough theoretical characterization indicates that the active oxidizing species is an asymmetric eta(2)-Ti-peroxo, absorbing in the visible range. The lability of the intermediate is found related to eta(2) <-> eta(1) interconversions of the Ti-peroxo structure. The interconversions, triggered by water molecules, could account for the experimentally found reduced catalytic activity in aged TS-1 catalysts. The results provide a microscopic picture of the reactivity and dehydration/aging processes of the catalyst fully consistent with experiments and highlight the fundamental role of the Lewis acid character of Ti in the formation, reactivity, and degradation of the active oxidizing species.
2006
DENSITY-FUNCTIONAL THEORY; MOLECULAR-DYNAMICS SIMULATION; TITANIUM ZEOLITES; HYDROGEN-PEROXIDE; AB-INITIO CALCULATIONS; CATALYSIS; EPOXIDATION
Spano, E.; Tabacchi, Gloria; Gamba, Aldo; Fois, ETTORE SILVESTRO
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11383/1499378
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