Thorsten Scherpf scite author profile

Thorsten Scherpf

3Publications

5Citation Statements Received

154Citation Statements Given

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148

Affiliations

University of Calgary

Publications

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A Mesoionic Carbene–Pyridine Bidentate Ligand That Improves Stability in Electrocatalytic CO₂ Reduction by a Molecular Manganese Catalyst

et al. 2022

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Tricarbonyl Group 7 complexes have a longstanding history as efficacious CO 2 electroreduction catalysts. Typically, these complexes feature an auxiliary 2,2′-bipyridine ligand that assists in redox steps by delocalizing the electron density into the ligand orbitals. While this feature lends to an accessible redox potential for CO 2 electroreduction, it also presents challenges for electrocatalysis with Mn because the electron density is removed from metal−ligand bonding orbitals. The results presented here thus introduce a mesoionic carbene (MIC) as a potent ligand platform to promote Mn-based electrocatalysis. The strong σ donation of the N,C-bidentate MIC is shown to help centralize the electron density on the Mn center while also maintaining relevant redox potentials for CO 2 electroreduction. Mechanistic investigation supports catalytic turnover at two operative potentials separated by 400 mV. In the low operating potential regime at −1.54 V, Mn(0) species catalyze CO 2 to CO and CO 3 2− , which has a maximum rate of 7 ± 5 s −1 and is stable for up to 30.7 h. At higher operating potential at −1.94 V, "Mn(−1)" catalyzes CO 2 to CO and H 2 O with faster turnovers of 200 ± 100 s −1 , with the trade-off being less stability at 6.7 h. The relative stabilities of Mn complexes bearing MIC and 4,4′-di-tert-butyl-2,2′-bipyridine were compared by evaluation under the same electrolysis conditions and therefore elucidated that the MIC promotes longevity for CO evolution throughout a 5 h period.

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A Mesoionic Carbene-Pyridine Bidentate Ligand Improves Stability in Electrocatalytic CO2 Reduction by a Molecular Manganese Catalyst

Scherpf

Carr

Donnelley

et al. 2022

Preprint

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Tricarbonyl group 7 complexes have a longstanding history as efficacious CO2 electroreduction catalysts. Typically, these complexes feature an auxiliary 2,2-bipyridine ligand which assists in redox steps by delocalizing electron density into the ligand-orbitals. While this feature lends to accessible redox potential for CO2 electroreduction, it also presents challenges for electrocatalysis with manganese, since the electron density is removed from metal-ligand bonding orbitals. The results presented here thus introduce mesoionic carbene (MIC) as a new potent ligand platform to promote Mn-based electrocatalysis. The strong σ-donation of the N,C-bidentate MIC is shown to help centralize electron density on the Mn-center while also maintaining relevant redox potentials for CO2 electroreduction. Mechanistic investigation supports catalytic turnover at two operative potentials separated by 400 mV. In the low overpotential regime, Mn(0) species catalyze CO2 to CO and CO32- with a maximum rate of 7 ± 5 s-1 and is stable for up to 30.7 h. At higher overpotential, “Mn(-1)” catalyzes CO2 to CO and H2O with faster turnovers of 200 ± 100 s-1 with the trade-off of being less stable at 6.7 h. The relative stability of Mn-complexes bearing MIC and 4-4’-diterbutyl-2,2’-bipyridine was compared by evaluating under the same electrolysis conditions, and therefore elucidated that the MIC promotes longevity for CO evolution through-out a 5 h period.

show abstract

A Mesoionic Carbene-Pyridine Bidentate Ligand Improves Stability in Electrocatalytic CO2 Reduction by a Molecular Manganese Catalyst

Scherpf

Carr

Donnelley

et al. 2022

Preprint

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