The interaction of CO, H2 and ethylene over a typical cobalt-based Fischer-Tropsch synthesis catalyst

Yusheng Zhang; Yali Yao; Jianli Chang; Joshua Gorimbo; Xinying Liu; Diane Hildebrandt

doi:10.1016/j.apcata.2021.118024

The interaction of CO, H₂ and ethylene over a typical cobalt-based Fischer-Tropsch synthesis catalyst

Yusheng Zhang
, Yali Yao
, Jianli Chang
, Joshua Gorimbo
, Xinying Liu
, Diane Hildebrandt

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

Abstract

Co-feeding ethylene to a Fischer-Tropsch synthesis (FTS) reactor exhibited multiple-effects, depending on the reaction conditions. Co-feeding a small amount resulted in a significant improvement in catalytic performance; however, both CO reactivity and chain-growth probability decreased when increasing ethylene concentration at a high temperature. This may be due to the "H-scavenging effect". Co-feeding CO into the ethylene hydrogenation system suppressed ethylene reactivity, which was seen as evidence of the CO "occupancy effect". This effect was dominant at low reaction temperatures, but weaker at high reaction temperatures. Both the CO “occupancy effect” and the “H-scavenging effect” of ethylene had a significant impact on the chain-growth reaction pathways. A new mechanism called the “ethylene-assisted CO-insertion mechanism” was hypothesised to explain the ethylene promotional effects on FTS. This mechanism may co-exist with both the CO-dissociation type mechanism and the ethylene hydrocracking chain-growth mechanism, and may allow the FTS product distribution to be tuned.

Original language	American English
Article number	118024
Journal	Applied Catalysis A: General
Volume	614
DOIs	https://doi.org/10.1016/j.apcata.2021.118024
State	Published - Mar 25 2021
Externally published	Yes

ASJC Scopus subject areas

Catalysis
Process Chemistry and Technology

Keywords

CO dissociation type mechanism
CO occupancy effect
Ethylene hydrocracking chain growth mechanism
Ethylene-Assisted CO insertion mechanism
H-scavenging effect of ethylene

Access to Document

10.1016/j.apcata.2021.118024

Cite this

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title = "The interaction of CO, H2 and ethylene over a typical cobalt-based Fischer-Tropsch synthesis catalyst",

abstract = "Co-feeding ethylene to a Fischer-Tropsch synthesis (FTS) reactor exhibited multiple-effects, depending on the reaction conditions. Co-feeding a small amount resulted in a significant improvement in catalytic performance; however, both CO reactivity and chain-growth probability decreased when increasing ethylene concentration at a high temperature. This may be due to the {"}H-scavenging effect{"}. Co-feeding CO into the ethylene hydrogenation system suppressed ethylene reactivity, which was seen as evidence of the CO {"}occupancy effect{"}. This effect was dominant at low reaction temperatures, but weaker at high reaction temperatures. Both the CO “occupancy effect” and the “H-scavenging effect” of ethylene had a significant impact on the chain-growth reaction pathways. A new mechanism called the “ethylene-assisted CO-insertion mechanism” was hypothesised to explain the ethylene promotional effects on FTS. This mechanism may co-exist with both the CO-dissociation type mechanism and the ethylene hydrocracking chain-growth mechanism, and may allow the FTS product distribution to be tuned.",

keywords = "CO dissociation type mechanism, CO occupancy effect, Ethylene hydrocracking chain growth mechanism, Ethylene-Assisted CO insertion mechanism, H-scavenging effect of ethylene",

author = "Yusheng Zhang and Yali Yao and Jianli Chang and Joshua Gorimbo and Xinying Liu and Diane Hildebrandt",

note = "Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",

year = "2021",

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doi = "10.1016/j.apcata.2021.118024",

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AU - Zhang, Yusheng

AU - Yao, Yali

AU - Chang, Jianli

AU - Gorimbo, Joshua

AU - Liu, Xinying

AU - Hildebrandt, Diane

PY - 2021/3/25

Y1 - 2021/3/25

N2 - Co-feeding ethylene to a Fischer-Tropsch synthesis (FTS) reactor exhibited multiple-effects, depending on the reaction conditions. Co-feeding a small amount resulted in a significant improvement in catalytic performance; however, both CO reactivity and chain-growth probability decreased when increasing ethylene concentration at a high temperature. This may be due to the "H-scavenging effect". Co-feeding CO into the ethylene hydrogenation system suppressed ethylene reactivity, which was seen as evidence of the CO "occupancy effect". This effect was dominant at low reaction temperatures, but weaker at high reaction temperatures. Both the CO “occupancy effect” and the “H-scavenging effect” of ethylene had a significant impact on the chain-growth reaction pathways. A new mechanism called the “ethylene-assisted CO-insertion mechanism” was hypothesised to explain the ethylene promotional effects on FTS. This mechanism may co-exist with both the CO-dissociation type mechanism and the ethylene hydrocracking chain-growth mechanism, and may allow the FTS product distribution to be tuned.

AB - Co-feeding ethylene to a Fischer-Tropsch synthesis (FTS) reactor exhibited multiple-effects, depending on the reaction conditions. Co-feeding a small amount resulted in a significant improvement in catalytic performance; however, both CO reactivity and chain-growth probability decreased when increasing ethylene concentration at a high temperature. This may be due to the "H-scavenging effect". Co-feeding CO into the ethylene hydrogenation system suppressed ethylene reactivity, which was seen as evidence of the CO "occupancy effect". This effect was dominant at low reaction temperatures, but weaker at high reaction temperatures. Both the CO “occupancy effect” and the “H-scavenging effect” of ethylene had a significant impact on the chain-growth reaction pathways. A new mechanism called the “ethylene-assisted CO-insertion mechanism” was hypothesised to explain the ethylene promotional effects on FTS. This mechanism may co-exist with both the CO-dissociation type mechanism and the ethylene hydrocracking chain-growth mechanism, and may allow the FTS product distribution to be tuned.

KW - CO dissociation type mechanism

KW - CO occupancy effect

KW - Ethylene hydrocracking chain growth mechanism

KW - Ethylene-Assisted CO insertion mechanism

KW - H-scavenging effect of ethylene

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