Mechanism of alkane dehydrogenation catalyzed by acidic zeolites: Ab initio transition path sampling

Tomas Bucko, Lubomir Benco, Orest Dubay, Christoph Dellago, Juergen Hafner

Publications: Contribution to journalArticlePeer Reviewed

Abstract

The dehydrogenation of propane over acidic chabazite has been studied using ab initio density-functional simulations in combination with static transition-state searches and dynamic transition path sampling (TPS) methods at elevated temperatures. The acidic zeolite has been modeled both using a small cluster and a large periodic model consisting of two unit cells, the TPS simulations allow to account for the effect of temperature and entropy. In agreement with experimental observations we find propene as the dominant reaction product and that the barrier for the dehydrogenation of a methyl group is higher than that for a methylene group. However, whereas all studies based on small cluster models (including the present one) conclude that the reaction proceeds via the formation of an alkoxy intermediate, our TPS studies based on a large periodic model lead to the conclusion that propene formation occurs via the formation of various forms of propyl cations stabilized by entropy, while the formation of an alkoxy species is a relatively rare event. It was observed only in 15% of the reactive trajectories for methyl dehydrogenation and even in only 8% of the methylene dehydrogenation reactions. Our studies demonstrate the importance of entropic effects and the need to account for the structure and flexibility of the zeolitic framework by using large periodic models.
Original languageEnglish
Article number214508
Number of pages11
JournalJournal of Chemical Physics
Volume131
Issue number21
DOIs
Publication statusPublished - 2009

Austrian Fields of Science 2012

  • 103009 Solid state physics
  • 103015 Condensed matter
  • 103025 Quantum mechanics
  • 103036 Theoretical physics

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