Litcius/Paper detail

Molecular Tuning of Reactivity of Zeolite Protons in HZSM-5

Yaxin Chen, Xinyou Ma, John H. Hack, Shuhao Zhang, Anyang Peng, James P. Dombrowski, Gregory A. Voth, Andrei Tokmakoff, Mayfair C. Kung, Harold H. Kung

2024Journal of the American Chemical Society10 citationsDOIOpen Access PDF

Abstract

In acidic HZSM-5 zeolite, the reactivity of a methanol molecule interacting with the zeolite proton is amenable to modification via coadsorbing a stochiometric amount of an electron density donor E to form the [( E )(CH 3 OH)(HZ)] complex. The rate of the methanol in this complex undergoing dehydration to dimethyl ether was determined for a series of E with proton affinity (PA) ranging from 659 kJ mol –1 for C 6 F 6 to 825 kJ mol –1 for C 4 H 8 O and was found to follow the expression: Ln(Rate) – Ln(Rate N 2 ) = β(PA – PA N 2 ) γ, where E = N 2 is the reference and β and γ are constants. This trend is probably due to the increased stability of the solvated proton in the [( E )(CH 3 OH)(HZ)] complex with increasing PA. Importantly, this is also observed in steady-state flow reactions when stoichiometric quantities of E are preadsorbed on the zeolite. As demonstrated with E being D 2 O, the effect on methanol reactivity diminishes when E is present in excess of the [( E )(CH 3 OH)(HZ)] complex. It is proposed that the methanol dehydration reaction involves [( E )(CH 3 OH)(CH 3 OH)(HZ)] as the transition state, which is supported by the isotopologue distribution of the initial dimethyl ether formed when a flow of CH 3 OH was passed over ZSM-5 containing one CD 3 OH per zeolite proton. The implication of this on the mechanism of catalytic methanol dehydration on HZSM-5 is discussed.

Topics & Concepts

ChemistryDimethyl etherZeoliteMethanolReactivity (psychology)Reaction rate constantStoichiometryProtonEtherIsotopologueMolecular sieveCatalysisPhysical chemistryMoleculeInorganic chemistryOrganic chemistryKineticsMedicinePhysicsPathologyQuantum mechanicsAlternative medicineZeolite Catalysis and SynthesisMetal-Organic Frameworks: Synthesis and ApplicationsCatalysis and Oxidation Reactions