Zeolite-encapsulated single-atom catalysts for efficient CO2 conversion

Zeolite-encapsulated single-atom catalysts for efficient CO2 conversion

[Display omitted] •Sc,Y,La,Ru,Rh,Ni,Pd,Pt@S-1 catalysts are great candidates for CO2 conversion.•Redox mechanism is preferred by groups 3–9 TM s.•Associative mechanism is preferred by group 10 T Ms.•Groups 11−12 T Ms are predicted to have poor CO2 conversion catalytic activity. Zeolite-supported sin...

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Bibliographic Details
Published in:Journal of CO2 utilization Vol. 54; p. 101777
Main Authors: Alonso, Gerard, López, Estefanía, Huarte-Larrañaga, Fermín, Sayós, Ramón, Prats, Hector, Gamallo, Pablo
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-12-2021
Subjects:
CO2 conversion
Density functional theory
Heterogeneous catalysis
MFI
Single-atom catalysts
Transition metals
Zeolites
MFI
Heterogeneous catalysis
Single-atom catalysts
Transition metals
Density functional theory
CO2 conversion
Zeolites
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Summary:[Display omitted] •Sc,Y,La,Ru,Rh,Ni,Pd,Pt@S-1 catalysts are great candidates for CO2 conversion.•Redox mechanism is preferred by groups 3–9 TM s.•Associative mechanism is preferred by group 10 T Ms.•Groups 11−12 T Ms are predicted to have poor CO2 conversion catalytic activity. Zeolite-supported single-atom catalysts (SACs) have emerged as a novel class of cheap and tuneable catalysts that can exhibit high activity, selectivity and stability. In this work, we conduct an extensive screening by means of density functional theory calculations to determine the usefulness of 3d, 4d and 5d transition metal (TM) SACs-supported in MFI-type Silicalite-1 zeolite for CO2 conversion. Two reaction mechanisms are considered, namely the redox - direct CO2 dissociation - and associative - hydrogen-assisted CO2 dissociation - mechanisms. Early TM SACs exhibit the lowest energy barriers, which follow the redox mechanism. These energy barriers raise when going right in the periodic table up to group 10, where they become prohibitive and the associative mechanism should dominate. By also considering their resistance to aggregation, we support the use of Sc, Y, La, Ru, Rh, Ni, Pd and Pt as potentially active and stable catalysts for CO2 conversion, given their low energy barriers and strong interaction with the zeolite framework.
ISSN:2212-9820
2212-9839
DOI:10.1016/j.jcou.2021.101777