Microkinetics modeling of the hydro-isomerization of n-hexane

A. Runstraat, van de; J. Grondelle, van; R.A. Santen, van

doi:10.1021/ie960661y

Microkinetics modeling of the hydro-isomerization of n-hexane

A. Runstraat, van de
, J. Grondelle, van
, R.A. Santen, van

Research output: Contribution to journal › Article › Academic › peer-review

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343 Downloads (Pure)

Abstract

The hydroisomerization of n-hexane over platinum-loaded mordenite and ZSM-5 was simulated using a microkinetics approach. Alkoxy species were assumed to be the reactive intermediates. Carbenium ions were considered to be part of the transition state. This leads to true activation energies of isomerization of approx. 130 kJ/mol for both zeolites. The model explicitly takes into account the variation in micropore filling. This enables modeling of the orders of the reaction over a wide pressure and adsorption enthalpy regime. The resulting model describes exptl. measurements very well. It is shown by both methods that ZSM-5 is more active per acid site than Mordenite due to its higher adsorption enthalpy for n-hexane. The effect is small because of the low hexane order. The adsorption entropy plays a decisive role in detg. the overall activity

Original language	English
Pages (from-to)	3116-3125
Number of pages	10
Journal	Industrial and Engineering Chemistry Research
Volume	36
Issue number	8
DOIs	https://doi.org/10.1021/ie960661y
Publication status	Published - 1997

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title = "Microkinetics modeling of the hydro-isomerization of n-hexane",

abstract = "The hydroisomerization of n-hexane over platinum-loaded mordenite and ZSM-5 was simulated using a microkinetics approach. Alkoxy species were assumed to be the reactive intermediates. Carbenium ions were considered to be part of the transition state. This leads to true activation energies of isomerization of approx. 130 kJ/mol for both zeolites. The model explicitly takes into account the variation in micropore filling. This enables modeling of the orders of the reaction over a wide pressure and adsorption enthalpy regime. The resulting model describes exptl. measurements very well. It is shown by both methods that ZSM-5 is more active per acid site than Mordenite due to its higher adsorption enthalpy for n-hexane. The effect is small because of the low hexane order. The adsorption entropy plays a decisive role in detg. the overall activity",

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year = "1997",

doi = "10.1021/ie960661y",

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journal = "Industrial and Engineering Chemistry Research",

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T1 - Microkinetics modeling of the hydro-isomerization of n-hexane

AU - Runstraat, van de, A.

AU - Grondelle, van, J.

AU - Santen, van, R.A.

PY - 1997

Y1 - 1997

N2 - The hydroisomerization of n-hexane over platinum-loaded mordenite and ZSM-5 was simulated using a microkinetics approach. Alkoxy species were assumed to be the reactive intermediates. Carbenium ions were considered to be part of the transition state. This leads to true activation energies of isomerization of approx. 130 kJ/mol for both zeolites. The model explicitly takes into account the variation in micropore filling. This enables modeling of the orders of the reaction over a wide pressure and adsorption enthalpy regime. The resulting model describes exptl. measurements very well. It is shown by both methods that ZSM-5 is more active per acid site than Mordenite due to its higher adsorption enthalpy for n-hexane. The effect is small because of the low hexane order. The adsorption entropy plays a decisive role in detg. the overall activity

AB - The hydroisomerization of n-hexane over platinum-loaded mordenite and ZSM-5 was simulated using a microkinetics approach. Alkoxy species were assumed to be the reactive intermediates. Carbenium ions were considered to be part of the transition state. This leads to true activation energies of isomerization of approx. 130 kJ/mol for both zeolites. The model explicitly takes into account the variation in micropore filling. This enables modeling of the orders of the reaction over a wide pressure and adsorption enthalpy regime. The resulting model describes exptl. measurements very well. It is shown by both methods that ZSM-5 is more active per acid site than Mordenite due to its higher adsorption enthalpy for n-hexane. The effect is small because of the low hexane order. The adsorption entropy plays a decisive role in detg. the overall activity

U2 - 10.1021/ie960661y

DO - 10.1021/ie960661y

M3 - Article

SN - 0888-5885

VL - 36

SP - 3116

EP - 3125

JO - Industrial and Engineering Chemistry Research

JF - Industrial and Engineering Chemistry Research

IS - 8

ER -

Microkinetics modeling of the hydro-isomerization of n-hexane

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