Adsorption of C2−C8 <i>n</i>-Alkanes in Zeolites

Moor, Bart A. De; Reyniers, Marie-Françoise; Gobin, Oliver C.; Lercher, Johannes A.; Marin, Guy

doi:10.1021/jp106536m

Cited by 191 publications

(353 citation statements)

References 57 publications

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“…Just as an example, in the work of Eder et al [29] and De Moor et al [53], adsorption was carried out at p  10 -3 mbar (9.87·10 -7 atm) of (propane to n-hexane) and T  400 K. In an analogous way in the work of Dunne et al [54], Ramachandran et al [28] and Ferreira et al [55], among others, adsorption was always performed at p  9.87·10 -5 atm and T  423 K. From the work presented here, it is clear that by working under those experimental conditions it should be very difficult to unequivocally conclude about the homogeneity or heterogeneity of the surface for adsorption sites. Then, one should either follow the methodology presented here or to perform adsorption measurements under the appropriate range of pressures and temperatures to ascertain the homo or heterogeneity of the zeolite surface for catalytic cracking.…”

Section: Differential Heat Of Adsorption (H Ads )mentioning

confidence: 99%

Catalytic cracking of n-alkane naphtha: The impact of olefin addition and active sites differentiation

Corma

Cuquerella

Miguel

2015

Journal of Catalysis

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An extended dual kinetic model allows to fit the n-heptane cracking results working in a wide range of reaction conditions. The duality of the model is provided by the contribution of monomolecular and bimolecular cracking mechanisms. It takes into account the role played by the olefins formed on the global cracking or added within the feed. Furthermore by means of this model and the kinetic parameters obtained when cracking n-heptane on ZSM-5, it has been observed that, while some characterization techniques show a homogeneous zeolite surface from the point of view of the active sites, rigorous kinetic experiments point to the possibility that the reactant sees a heterogeneous surface with, at least, two group of cracking active sites. Those differentiated active sites give different cracking rates and different activation energies for the process and, in the case of ZSM-5, could be assimilated to sites pointing to the 10R channels and sites pointing into the crossing of the 10R channels, mainly due to differences in acid site location and confinement effects.3

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Section: Differential Heat Of Adsorption (H Ads )mentioning

confidence: 99%

Catalytic cracking of n-alkane naphtha: The impact of olefin addition and active sites differentiation

Corma

Cuquerella

Miguel

2015

Journal of Catalysis

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“…Eqs. (3) and (4)) are not very different from each other (see Table 6); however, the latter equation was employed since it has often been used for fitting volatile organic compounds adsorption on zeolites [29]. The fitted saturation capacity of MOR (see Table 6) is higher for toluene than for MTBE.…”

Section: Batch Experimentsmentioning

confidence: 99%

Location of MTBE and toluene in the channel system of the zeolite mordenite: Adsorption and host–guest interactions

Arletti

Martucci

Alberti

et al. 2012

Journal of Solid State Chemistry

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a b s t r a c tThis paper reports a study of the location of Methyl Tertiary Butyl Ether (MTBE) and toluene molecules adsorbed in the pores of the organophylic zeolite mordenite from an aqueous solution. The presence of these organic molecules in the zeolite channels was revealed by structure refinement performed by the Rietveld method. About 3 molecules of MTBE and 3.6 molecules of toluene per unit cell were incorporated into the cavities of mordenite, representing 75% and 80% of the total absorption capacity of this zeolite. In both cases a water molecule was localized inside the side pocket of mordenite. The saturation capacity determined by the adsorption isotherms, obtained by batch experiments, and the weight loss given by thermogravimetric (TG) analyses were in very good agreement with these values. The interatomic distances obtained after the structural refinements suggest MTBE could be connected to the framework through a water molecule, while toluene could be bonded to framework oxygen atoms. The rapid and high adsorption of these hydrocarbons into the organophylic mordenite zeolite makes this cheap and environmental friendly material a suitable candidate for the removal of these pollutants from water.

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“…Entropies of activation are negative and have values between 40.6 (ethane) and 47.6 (n-butane/1) cal K -1 mol -1 for the proton exchange reaction in ZSM-5. From the Arrhenius equation, the entropy term contributes to the prefactor [35] and, thus, it slows down the proton exchange rate. Apparent Gibbs energies of activation at 500 K are in the range of 30.3 (ethane) to 40.6 (i-butane/3) kcal/mol.…”

Section: Apparent Reaction Barriersmentioning

confidence: 99%

“…De Moor et al[35] using QM-Pot(MP2//B3LYP) have shown that adsorption enthalpies of n-alkanes (C2-C8) in H-FAU, H-BEA,…”

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confidence: 99%

Proton exchange reactions of C2–C4 alkanes sorbed in ZSM-5 zeolite

et al. 2012

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An extensive theoretical study has been carried out to determine barriers for the proton exchange reactions of C2-C4 alkanes in ZSM-5. It was found that cluster size and cavity structure are very important for predicting this barrier. A decrement of up to 20 kcal/mol was observed when employing the periodic model instead of using the small cluster model. Effects of basis set quality and electron correlation to the activation energy are positive and in combination could contribute up to 8 kcal/mol. An extrapolation scheme for estimating the reaction barrier that takes into account effects of cluster size, basis set quality, and electron correlation has been proposed. The regioselectivity and the chain length were discussed.

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Adsorption of C2−C8 n-Alkanes in Zeolites

Cited by 191 publications

References 57 publications

Catalytic cracking of n-alkane naphtha: The impact of olefin addition and active sites differentiation

Catalytic cracking of n-alkane naphtha: The impact of olefin addition and active sites differentiation

Location of MTBE and toluene in the channel system of the zeolite mordenite: Adsorption and host–guest interactions

Proton exchange reactions of C2–C4 alkanes sorbed in ZSM-5 zeolite

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