Operando Spectroelectrochemistry Unravels the Mechanism of CO<sub>2</sub> Electrocatalytic Reduction by an Fe Porphyrin

Salamé, Aude; Hon Cheah, Mun; Bonin, Julien; Robert, Marc; Anxolabéhère‐Mallart, Elodie

doi:10.1002/anie.202412417

Angew Chem Int Ed

2024

DOI: 10.1002/anie.202412417

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Operando Spectroelectrochemistry Unravels the Mechanism of CO₂ Electrocatalytic Reduction by an Fe Porphyrin

Aude Salamé,

Mun Hon Cheah,

Julien Bonin

et al.

Abstract: Iron porphyrins are molecular catalysts recognized for their ability to electrochemically and photochemically reduce carbon dioxide (CO2). The main reduction product is carbon monoxide (CO). CO holds significant industrial importance as it serves as a precursor for various valuable chemical products containing either a single carbon atom (C1), like methanol or methane, or multiple carbon atoms (Cn), such as ethanol or ethylene. Despite the long‐established efficiency of these catalysts, optimizing their cataly… Show more

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Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO₂ to Isoelectronic N₂O

Chartier,

Deeba,

Collard

et al. 2024

ACS Catal.

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The electrochemical reductive deoxygenation of N 2 O catalyzed by iron tetraphenylporphyrin (TPPFe) is studied and compared to the electroreduction of CO 2 to CO by the same catalyst. We show that the electroreduction of N 2 O is catalyzed by TPPFe(I), albeit at a slower rate compared to that of TPPFe(0). On a similar time scale, CO 2 does not react with TPPFe(I). The catalytic reduction of N 2 O by TPPFe(I) is however endowed by a self-modulation process due to the production of hydroxide ions as a coproduct that bind to TPPFe(II) and slow down the regeneration of the TPPFe(I) catalytic active species. Two catalytic cycles are thus intertwined when the electrocatalysis is run at a potential where TPPFe(0) is generated, and the resting state in solution is TPPFe(II)(OH) and not TPPFe(I), as opposed to the case of CO 2 catalytic reductive deoxygenation. Revealing the shift of the active catalysis from TPPFe(0) to TPPFe(I) opens the way toward the design of molecular catalysts for N 2 O reductive deoxygenation at a lower overpotential.

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Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO₂ to Isoelectronic N₂O

Chartier,

Deeba,

Collard

et al. 2024

ACS Catal.

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show abstract

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Operando Spectroelectrochemistry Unravels the Mechanism of CO₂ Electrocatalytic Reduction by an Fe Porphyrin

Cited by 1 publication

References 51 publications

Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO₂ to Isoelectronic N₂O

Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO₂ to Isoelectronic N₂O

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Operando Spectroelectrochemistry Unravels the Mechanism of CO2 Electrocatalytic Reduction by an Fe Porphyrin

Cited by 1 publication

References 51 publications

Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO2 to Isoelectronic N2O

Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO2 to Isoelectronic N2O

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Product

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Operando Spectroelectrochemistry Unravels the Mechanism of CO₂ Electrocatalytic Reduction by an Fe Porphyrin

Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO₂ to Isoelectronic N₂O

Iron(I) Tetraphenylporphyrin Is an Active Catalyst in Reductive Deoxygenation when Switching from CO₂ to Isoelectronic N₂O