Recent trend of metal promoter role for CO2 hydrogenation to C1 and C2+ products

•Different metal promoters result in different selectivity of the C1 (methanol and methane) and C2+ (olefin) products on CO2 hydrogenation.•Metal promoters modify the hydrogen dissociation potential and surface oxygen vacancy.•Promoter will be able to stabilize the intermediate and to maneuver catal...

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Veröffentlicht in:South African journal of chemical engineering 2023-04, Vol.44, p.14-30
Hauptverfasser: Sholeha, Novia Amalia, Holilah, Holilah, Bahruji, Hasliza, Ayub, Athirah, Widiastuti, Nurul, Ediati, Ratna, Jalil, Aishah Abdul, Ulfa, Maria, Masruchin, Nanang, Nugraha, Reva Edra, Prasetyoko, Didik
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Sprache:eng
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Zusammenfassung:•Different metal promoters result in different selectivity of the C1 (methanol and methane) and C2+ (olefin) products on CO2 hydrogenation.•Metal promoters modify the hydrogen dissociation potential and surface oxygen vacancy.•Promoter will be able to stabilize the intermediate and to maneuver catalytic reaction pathway into desired products for CO2 hydrogenation to longer chain molecules. CO2 hydrogenation as sustainable route for generation of value-added carbon feedstock is identified as green pathway for mitigation of greenhouse gasses emission. CO2 methanation is one of the promising solutions, which only requires reactions at atmospheric pressure while utilizing metal catalysts to overcome kinetic limitations. Metal catalysts can be promoted to alter reducibities, CO2 adsorption capacities, and H2CO2 dissociation potential. The role of metal promoter such as rare earth elements (Ce, Mn, Co, and La) and alkali and alkali earth metal (Li, Na, Ca, and K) will be discussed within the scope of CO2 methanation. The aspect of catalysts modification towards hydrogen dissociation potential and surface oxygen vacancy will be emphasized to enhance selectivity for methane. Another pathway for CO2 hydrogenation is via further conversion into longer chain molecules such as olefin and ethanol. The benefit of metal promoter will be discussed in this review on the effect towards promoting CC coupling reaction for producing longer chain alcohol and light olefin. The strategies to develop active catalysts for the coupling reaction of CC will be emphasized with the promoter introduction. For the hydrogenation of CO2 to longer chain molecules, the main metal catalysts Ni, Pd, Rh, and Co, and their modification with promoter such as Ga, Cu, and alkali metal Na, K will be discussed. A critical analysis of the CO2 methanation mechanism and further CC reaction to longer chain molecules will be discussed, particularly the effect of metal promoters to stabilize the intermediate and maneuver the catalytic reaction pathway into the desired products. [Display omitted]
ISSN:1026-9185
DOI:10.1016/j.sajce.2023.01.002