Understanding cage effects in the n-alkane conversion on zeolites

Maesen, Theo L. M.; Beerdsen, E.; Calero, Sofı́a; Dubbeldam, David; Smit, Berend

doi:10.1016/j.jcat.2005.11.007

Cited by 65 publications

(83 citation statements)

References 84 publications

(184 reference statements)

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“…The topologies in red have been patented by Shell 541 and ExxonMobil, 542 and GON has been "discovered" by simulations. 544 …”

Section: Discussionmentioning

confidence: 99%

“…For example, branched alkanes (and alkenes) can contribute the majority of the hydrocracking products to the desorbed product phase while the branched alkane portion of the desorbed phase remains minute. 359,504 Under such conditions, the gas phase and adsorbed phase can no longer equilibrate and the free-energy landscape imposed by the zeolite topology on the reacting system will leave its signature on the product distribution. Such a lack of equilibration between gas phase and adsorbed phase is endemic to larger molecules in industrial processes such as we consider here.…”

Section: New Mechanism: the Free Energy Landscapementioning

confidence: 99%

“…In the Henry regime the simulated parameter characterizing n-alkane reactivity (product of Henry constant and diffusion coefficient) reproduces the experimental reactivity remarkable well. 504 …”

Section: Reactant Shape Selectivitymentioning

confidence: 99%

See 2 more Smart Citations

Molecular Simulations of Zeolites: Adsorption, Diffusion, and Shape Selectivity

2008

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“…The topologies in red have been patented by Shell 541 and ExxonMobil, 542 and GON has been "discovered" by simulations. 544 …”

Section: Discussionmentioning

confidence: 99%

Section: New Mechanism: the Free Energy Landscapementioning

confidence: 99%

See 1 more Smart Citation

Molecular Simulations of Zeolites: Adsorption, Diffusion, and Shape Selectivity

2008

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“…The small entry pore is selective toward linear paraffins, and cracking can occur on sites within the supercage to produce smaller chain alkanes. 70 Zeolite A is also widely used in in ion-exchange separation. 71 We find a slightly smaller value for R ctw in chabazite-type (CHA) zeolite.…”

Section: Zeolite Structuresmentioning

confidence: 99%

Loading Dependence of the Diffusion Coefficient of Methane in Nanoporous Materials

2006

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In this work, we use molecular simulations to study the loading dependence of the self-and collective diffusion coefficients of methane in various zeolite structures. To arrive at a microscopic interpretation of the loading dependence, we interpret the diffusion behavior in terms of hopping rates over a free-energy barrier. These free-energy barriers are computed directly from a molecular simulation. We show that these free-energy profiles are a convenient starting point to explain a particular loading dependence of the diffusion coefficient. On the basis of these observations, we present a classification of zeolite structures for the diffusion of methane as a function of loading: three-dimensional cagelike structures, one-dimensional channels, and intersecting channels. Structures in each of these classes have their loading dependence of the free-energy profiles in common. An important conclusion of this work is that diffusion in nanoporous materials can never be described by one single effect so that we need to distinguish different loading regimes to describe the diffusion over the entire loading range.

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“…A lower free energy of adsorption is a measure of a higher concentration inside the zeolite, and a higher reactivity. Experimentally, insights into reactant shape selectivity due to differences in free energy of adsorption have been obtained in studies on the chain lengthdependence of the reactivity of n-alkanes [26,122,123], so that the discrimination of zeolites between n-alkanes of various lengths depends on the pore topology. To the extent that the reactivity of n-alkanes as a function of chain length varies with zeolite topology, it is -by definition [14] -an example of (reactant) shape selectivity.…”

Section: Gas-phasementioning

confidence: 99%

Computer Simulations of Shape Selectivity Effects

Smit¹,

Maesen

2008

Handbook of Heterogeneous Catalysis

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Introduction Today, almost every gasoline molecule has seen the interior of a zeolite and experienced the effect of shape selectivity. Given the economical importance [1][2][3][4][5] implied by this statement, one would expect that we have a very good understanding of the mechanisms underlying shape selectivity. Clearly, we do have a very good understanding of the chemical reactions that take place inside the pores of a zeolite. In addition, many mechanisms have been proposed to explain the various product distributions that have been observed experimentally. However, we are still very far away that by looking at a zeolite structure we can provide a prediction of the products.Let us consider as a simple example the conversion of n-decane in an acid zeolite. The chemistry tells us that isomerization reactions take place giving mono-, di-, and tribranched isomers. These isomerization reactions compete with cracking, and this results in a large number * Corresponding author.

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Understanding cage effects in the n-alkane conversion on zeolites

Cited by 65 publications

References 84 publications

Molecular Simulations of Zeolites: Adsorption, Diffusion, and Shape Selectivity

Molecular Simulations of Zeolites: Adsorption, Diffusion, and Shape Selectivity

Loading Dependence of the Diffusion Coefficient of Methane in Nanoporous Materials

Computer Simulations of Shape Selectivity Effects

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