Fischer-Tropsch Product Selectivity Modulation via an FeRh Nanocluster Composition Design

Sin Mu Jhan; Ho Liang Hsu; Chun Chih Chang; Elise Y. Li

doi:10.1021/acs.jpcc.0c03274

Fischer-Tropsch Product Selectivity Modulation via an FeRh Nanocluster Composition Design

Sin Mu Jhan, Ho Liang Hsu, Chun Chih Chang^*, Elise Y. Li^*

^*Corresponding author for this work

Department of Chemistry

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

1 Citation (Scopus)

Abstract

The reaction mechanism of*CHx formation in Fischer-Tropsch synthesis on various FeRh nanoclusters is studied using DFT calculations. We find that the energy barrier of*CH2 formation from hydrogen-assisted*CH2O dissociation can be directly modulated using the Fe/Rh composition ratio. Thermodynamic investigations and the natural bond orbital (NBO) analysis indicate that the barrier dropping of C-O bond scission in*CH2O can be ascribed to the interaction between the Fe and the O atoms. In particular, the*CH2 formation can be selectively stabilized with respect to the*CH3O formation using a local tri-Fe configuration on the FeRh nanocluster when the Fe ratio exceeds 50%. An optimal barrier may be achieved by carefully balancing the number of Rh and Fe atoms in the local configuration of the active site to stabilize both ends of the intermediates.

Original language	English
Pages (from-to)	15225-15230
Number of pages	6
Journal	Journal of Physical Chemistry C
Volume	124
Issue number	28
DOIs	https://doi.org/10.1021/acs.jpcc.0c03274
Publication status	Published - 2020 Jul 16

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
General Energy
Physical and Theoretical Chemistry
Surfaces, Coatings and Films

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10.1021/acs.jpcc.0c03274

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title = "Fischer-Tropsch Product Selectivity Modulation via an FeRh Nanocluster Composition Design",

abstract = "The reaction mechanism of*CHx formation in Fischer-Tropsch synthesis on various FeRh nanoclusters is studied using DFT calculations. We find that the energy barrier of*CH2 formation from hydrogen-assisted*CH2O dissociation can be directly modulated using the Fe/Rh composition ratio. Thermodynamic investigations and the natural bond orbital (NBO) analysis indicate that the barrier dropping of C-O bond scission in*CH2O can be ascribed to the interaction between the Fe and the O atoms. In particular, the*CH2 formation can be selectively stabilized with respect to the*CH3O formation using a local tri-Fe configuration on the FeRh nanocluster when the Fe ratio exceeds 50%. An optimal barrier may be achieved by carefully balancing the number of Rh and Fe atoms in the local configuration of the active site to stabilize both ends of the intermediates.",

author = "Jhan, {Sin Mu} and Hsu, {Ho Liang} and Chang, {Chun Chih} and Li, {Elise Y.}",

note = "Publisher Copyright: Copyright {\textcopyright} 2020 American Chemical Society.",

year = "2020",

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doi = "10.1021/acs.jpcc.0c03274",

language = "English",

volume = "124",

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T1 - Fischer-Tropsch Product Selectivity Modulation via an FeRh Nanocluster Composition Design

AU - Jhan, Sin Mu

AU - Hsu, Ho Liang

AU - Chang, Chun Chih

AU - Li, Elise Y.

PY - 2020/7/16

Y1 - 2020/7/16

N2 - The reaction mechanism of*CHx formation in Fischer-Tropsch synthesis on various FeRh nanoclusters is studied using DFT calculations. We find that the energy barrier of*CH2 formation from hydrogen-assisted*CH2O dissociation can be directly modulated using the Fe/Rh composition ratio. Thermodynamic investigations and the natural bond orbital (NBO) analysis indicate that the barrier dropping of C-O bond scission in*CH2O can be ascribed to the interaction between the Fe and the O atoms. In particular, the*CH2 formation can be selectively stabilized with respect to the*CH3O formation using a local tri-Fe configuration on the FeRh nanocluster when the Fe ratio exceeds 50%. An optimal barrier may be achieved by carefully balancing the number of Rh and Fe atoms in the local configuration of the active site to stabilize both ends of the intermediates.

AB - The reaction mechanism of*CHx formation in Fischer-Tropsch synthesis on various FeRh nanoclusters is studied using DFT calculations. We find that the energy barrier of*CH2 formation from hydrogen-assisted*CH2O dissociation can be directly modulated using the Fe/Rh composition ratio. Thermodynamic investigations and the natural bond orbital (NBO) analysis indicate that the barrier dropping of C-O bond scission in*CH2O can be ascribed to the interaction between the Fe and the O atoms. In particular, the*CH2 formation can be selectively stabilized with respect to the*CH3O formation using a local tri-Fe configuration on the FeRh nanocluster when the Fe ratio exceeds 50%. An optimal barrier may be achieved by carefully balancing the number of Rh and Fe atoms in the local configuration of the active site to stabilize both ends of the intermediates.

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Fischer-Tropsch Product Selectivity Modulation via an FeRh Nanocluster Composition Design

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