Insight into the effects of confined hydrocarbon species on the lifetime of methanol conversion catalysts

I. Lezcano-Gonzalez; E. Campbell; A. E.J. Hoffman; M. Bocus; I. V. Sazanovich; M. Towrie; M. Agote-Aran; E. K. Gibson; A. Greenaway; K. De Wispelaere; V. Van Speybroeck; A. M. Beale

doi:10.1038/s41563-020-0800-y

Insight into the effects of confined hydrocarbon species on the lifetime of methanol conversion catalysts

I. Lezcano-Gonzalez^*, E. Campbell, A. E.J. Hoffman, M. Bocus, I. V. Sazanovich, M. Towrie, M. Agote-Aran, E. K. Gibson, A. Greenaway, K. De Wispelaere, V. Van Speybroeck^*, A. M. Beale^*

^*Corresponding author for this work

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

Abstract

The methanol-to-hydrocarbons reaction refers collectively to a series of important industrial catalytic processes to produce either olefins or gasoline. Mechanistically, methanol conversion proceeds through a ‘pool’ of hydrocarbon species. For the methanol-to-olefins process, these species can be delineated broadly into ‘desired’ lighter olefins and ‘undesired’ heavier fractions that cause deactivation in a matter of hours. The crux in further catalyst optimization is the ability to follow the formation of carbonaceous species during operation. Here, we report the combined results of an operando Kerr-gated Raman spectroscopic study with state-of-the-art operando molecular simulations, which allowed us to follow the formation of hydrocarbon species at various stages of methanol conversion. Polyenes are identified as crucial intermediates towards formation of polycyclic aromatic hydrocarbons, with their fate determined largely by the zeolite topology. Notably, we provide the missing link between active and deactivating species, which allows us to propose potential design rules for future-generation catalysts.

Original language	English
Pages (from-to)	1081-1087
Number of pages	7
Journal	Nature Materials
Volume	19
Issue number	10
DOIs	https://doi.org/10.1038/s41563-020-0800-y
Publication status	Published - 1 Oct 2020
Externally published	Yes

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Lezcano-Gonzalez, I., Campbell, E., Hoffman, A. E. J., Bocus, M., Sazanovich, I. V., Towrie, M., Agote-Aran, M., Gibson, E. K., Greenaway, A., De Wispelaere, K., Van Speybroeck, V., & Beale, A. M. (2020). Insight into the effects of confined hydrocarbon species on the lifetime of methanol conversion catalysts. Nature Materials, 19(10), 1081-1087. https://doi.org/10.1038/s41563-020-0800-y

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title = "Insight into the effects of confined hydrocarbon species on the lifetime of methanol conversion catalysts",

abstract = "The methanol-to-hydrocarbons reaction refers collectively to a series of important industrial catalytic processes to produce either olefins or gasoline. Mechanistically, methanol conversion proceeds through a {\textquoteleft}pool{\textquoteright} of hydrocarbon species. For the methanol-to-olefins process, these species can be delineated broadly into {\textquoteleft}desired{\textquoteright} lighter olefins and {\textquoteleft}undesired{\textquoteright} heavier fractions that cause deactivation in a matter of hours. The crux in further catalyst optimization is the ability to follow the formation of carbonaceous species during operation. Here, we report the combined results of an operando Kerr-gated Raman spectroscopic study with state-of-the-art operando molecular simulations, which allowed us to follow the formation of hydrocarbon species at various stages of methanol conversion. Polyenes are identified as crucial intermediates towards formation of polycyclic aromatic hydrocarbons, with their fate determined largely by the zeolite topology. Notably, we provide the missing link between active and deactivating species, which allows us to propose potential design rules for future-generation catalysts.",

author = "I. Lezcano-Gonzalez and E. Campbell and Hoffman, {A. E.J.} and M. Bocus and Sazanovich, {I. V.} and M. Towrie and M. Agote-Aran and Gibson, {E. K.} and A. Greenaway and {De Wispelaere}, K. and {Van Speybroeck}, V. and Beale, {A. M.}",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s), under exclusive licence to Springer Nature Limited.",

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Lezcano-Gonzalez, I, Campbell, E, Hoffman, AEJ, Bocus, M, Sazanovich, IV, Towrie, M, Agote-Aran, M, Gibson, EK, Greenaway, A, De Wispelaere, K, Van Speybroeck, V & Beale, AM 2020, 'Insight into the effects of confined hydrocarbon species on the lifetime of methanol conversion catalysts', Nature Materials, vol. 19, no. 10, pp. 1081-1087. https://doi.org/10.1038/s41563-020-0800-y

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AU - Lezcano-Gonzalez, I.

AU - Campbell, E.

AU - Hoffman, A. E.J.

AU - Bocus, M.

AU - Sazanovich, I. V.

AU - Towrie, M.

AU - Agote-Aran, M.

AU - Gibson, E. K.

AU - Greenaway, A.

AU - De Wispelaere, K.

AU - Van Speybroeck, V.

AU - Beale, A. M.

PY - 2020/10/1

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N2 - The methanol-to-hydrocarbons reaction refers collectively to a series of important industrial catalytic processes to produce either olefins or gasoline. Mechanistically, methanol conversion proceeds through a ‘pool’ of hydrocarbon species. For the methanol-to-olefins process, these species can be delineated broadly into ‘desired’ lighter olefins and ‘undesired’ heavier fractions that cause deactivation in a matter of hours. The crux in further catalyst optimization is the ability to follow the formation of carbonaceous species during operation. Here, we report the combined results of an operando Kerr-gated Raman spectroscopic study with state-of-the-art operando molecular simulations, which allowed us to follow the formation of hydrocarbon species at various stages of methanol conversion. Polyenes are identified as crucial intermediates towards formation of polycyclic aromatic hydrocarbons, with their fate determined largely by the zeolite topology. Notably, we provide the missing link between active and deactivating species, which allows us to propose potential design rules for future-generation catalysts.

AB - The methanol-to-hydrocarbons reaction refers collectively to a series of important industrial catalytic processes to produce either olefins or gasoline. Mechanistically, methanol conversion proceeds through a ‘pool’ of hydrocarbon species. For the methanol-to-olefins process, these species can be delineated broadly into ‘desired’ lighter olefins and ‘undesired’ heavier fractions that cause deactivation in a matter of hours. The crux in further catalyst optimization is the ability to follow the formation of carbonaceous species during operation. Here, we report the combined results of an operando Kerr-gated Raman spectroscopic study with state-of-the-art operando molecular simulations, which allowed us to follow the formation of hydrocarbon species at various stages of methanol conversion. Polyenes are identified as crucial intermediates towards formation of polycyclic aromatic hydrocarbons, with their fate determined largely by the zeolite topology. Notably, we provide the missing link between active and deactivating species, which allows us to propose potential design rules for future-generation catalysts.

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Insight into the effects of confined hydrocarbon species on the lifetime of methanol conversion catalysts

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