Journal of Catalysis, Vol.283, No.1, 98-107, 2011
Catalytic consequences of hydroxyl group location on the kinetics of n-hexane hydroisomerization over acidic zeolites
The measured kinetics of n-C(6)H(14) hydroisomerization reactions is consistent with a bifunctional mechanism involving the facile dehydrogenation of n-hexane on the metal catalyst and a kinetically relevant step involving isomerization of n-hexene on zeolitic acidic sites. The measured activation entropy in small 8-MR pockets of MOR (-35 J mol(-1) K(-1)) is similar to that in larger 12-MR channels of MOR (-37 J mol(-1) K(-1)) and BEA (-33 J mol(-1) K(-1)) but higher than that in medium pore FER (-86 J mol(-1) K(-1)), suggesting that partial confinement of C(6) olefinic reactants results in lower free energy for the isomerization reaction in 8-MR pockets of MOR. The hypothesis that a cyclopropane-like cationic transition state is not completely contained within the 8-MR pockets of MOR is consistent with the observed selectivity to 2-methylpentane and 3-methylpentane in the 8-MR pockets being identical to that measured in larger 12-MR channels of MOR and BEA. The lower activation energy measured in 8-MR pockets compared to larger 12-MR channels of MOR may arise due to greater electrostatic stabilization of the positively charged transition state by framework oxygen atoms located on the pore mouth of the smaller 8-MR pockets of MOR or due to the larger heat of adsorption caused by confinement in smaller 8-MR pockets. The lower activation energy in 8-MR channels and comparable loss in entropy mediated by partial confinement results in the rate per proton in 8-MR pockets being five times larger than the rate in 12-MR channels of MOR. These results provide another conceptual consideration for rigorous and quantitative understanding of local environment effects of zeolite channel size and connectivity on the rate and selectivity of acid-catalyzed reactions. (C) 2011 Elsevier Inc. All rights reserved.
Keywords:Alkane hydroisomerization;Zeolite;Mordenite;Bifunctional catalysis;Shape selectivity;Partial confinement;Entropy-driven reactions;Electrostatic stabilization