Exploring the impact of cobalt and H2 to CO ratios on catalytic performance of FeKAl and FeCoKAl catalysts in CO hydrogenation to light olefins

[Display omitted] •Higher H2:CO boosts hydrogenation over CO2 formation.•Increased H2:CO lowers carbon fiber buildup.•Co enhances moderate H2 adsorption and weak-to-medium basic sites.•Co aids desorption, reduces wax for better stability.•Co enhances iron oxide reduction, stabilizing CO2 and hydroca...

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Bibliographic Details
Published in:Fuel (Guildford) 2025-03, Vol.383, p.133833, Article 133833
Main Authors: Dolsiririttigul, Napaphut, Numpilai, Thanapha, Faungnawakij, Kajornsak, Chareonpanich, Metta, Rupprechter, Günther, Witoon, Thongthai
Format: Article
Language:English
Subjects:
Carbon formation
H2 to CO ratios
Hydrogenation
Light olefins
Stability
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Summary:[Display omitted] •Higher H2:CO boosts hydrogenation over CO2 formation.•Increased H2:CO lowers carbon fiber buildup.•Co enhances moderate H2 adsorption and weak-to-medium basic sites.•Co aids desorption, reduces wax for better stability.•Co enhances iron oxide reduction, stabilizing CO2 and hydrocarbon yields. This study explores the CO hydrogenation to light olefins over FeKAl catalysts, examining how varying H2 to CO ratios (from 1:1 to 7:1) and the introduction of cobalt (Co) influence catalytic performance. Our investigation reveals that Co addition significantly enhances the reducibility of iron oxide species and increases sites favorable for moderate hydrogen adsorption and weak to moderate basicity. We discovered that without Co (FeKAl), increasing the H2 to CO ratio progressively lowers CO2 space–time yield (STY), shifting the reaction’s preference from the water–gas shift reaction towards hydrogenation. The STY of light olefins reaches a peak at an H2 to CO ratio of 3:1, indicating optimal conditions for their production before decreasing at higher ratios. Incorporation of Co (FeCoKAl) maintains this trend but with marked improvements in CO conversion and olefin STY, especially notable at a ratio of 1:1 due to enhanced hydrocarbon product desorption. The findings underscore the critical role of Co and H2 to CO ratios in modulating catalyst stability and activity, with specific ratios significantly reducing catalyst deactivation through diminished wax and carbon fiber formation, and Co presence aiding in the maintenance of steady CO2, hydrocarbon, and light olefin yields by preventing the excessive transformation of iron carbide to Fe3O4.
ISSN:0016-2361
DOI:10.1016/j.fuel.2024.133833