A comprehensive density functional theory study of ethane dehydrogenation over reduced extra-framework gallium species in ZSM-5 zeolite

E.A. Pidko, V.B. Kazansky, E.J.M. Hensen, R.A. Santen, van

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Samenvatting

The stability of various gallium species (Ga+, , and GaH+2) as models for the active sites in reduced Ga/ZSM-5 and the possible reaction paths of alkane dehydrogenation were studied using a density functional theory cluster modeling approach. In general, alkanes are preferentially activated via an "alkyl" mechanism, in which gallium acts as an acceptor of the alkyl group. A comparison of the computed energetics of the various reaction paths for ethane indicates that the catalytic reaction most likely proceeds over Ga+. The initial step of CH activation is the oxidative addition of an alkane molecule to the Ga+ cation, which proceeds via an indirect heterolytic mechanism involving the basic oxygen atoms of the zeolite lattice. Although the catalytic reaction can also occur over and GaH+2 sites, these paths are not favored. Decomposition of leading to formation of Ga+ during the catalytic cycle is more favorable than regeneration of these sites. The reactivity of GaH+2 ions is strongly dependent on the distance between the stabilizing aluminum-occupied oxygen tetrahedra. In cases of greater AlAl distances, the stability of the GaH+2 species is very low, and it decomposes to Ga+ and a Brønsted acid site, whereas when Al atoms are located more closely, the charge-compensating GaH+2 ions are the most stable and exhibit the lowest activity for the initial CH bond cleavage reaction.
Originele taal-2Engels
Pagina's (van-tot)73-84
Aantal pagina's12
TijdschriftJournal of Catalysis
Volume240
Nummer van het tijdschrift1
DOI's
StatusGepubliceerd - 2006

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