Probing the Fen+/Fe(n−1)+ redox potential of Fe phthalocyanines and Fe porphyrins as a reactivity descriptor in the electrochemical oxidation of cysteamine

Silva, Nataly; Calderón, Sebastián; Páez, Maritza; Oyarzún, María Paz; Koper, Marc T. M.; Zagal, José H.

doi:10.1016/j.jelechem.2017.12.068

Cited by 24 publications

(21 citation statements)

References 44 publications

(48 reference statements)

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“…The pyrrolic N ligands may stabilize Fe 3+ relative to Fe 2+ , whereas the pyridinic N ligands have the opposite effect. Thermodynamically, the respective reduction potentials support this hypothesis: The standard reduction potential of [Fe(phen) 3 ] 3+/2+ is 1.06 V versus SHE, whereas that of Fe 3+/2+ couple in Fe-porphyrin complexes can reach as low as -0.4 V versus SHE (31). Preservation of the +3 oxidation state during CO 2 electroreduction is counterintuitive because the formation of highly reduced, low-valent Fe species is necessary for molecular Fe catalysts (32).…”

Section: E F H G Bmentioning

confidence: 78%

Atomically dispersed Fe ³⁺ sites catalyze efficient CO ₂ electroreduction to CO

Hsu

Bai

et al. 2019

Science

1,233

718

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Currently, the most active electrocatalysts for the conversion of CO2 to CO are gold-based nanomaterials, whereas non–precious metal catalysts have shown low to modest activity. Here, we report a catalyst of dispersed single-atom iron sites that produces CO at an overpotential as low as 80 millivolts. Partial current density reaches 94 milliamperes per square centimeter at an overpotential of 340 millivolts. Operando x-ray absorption spectroscopy revealed the active sites to be discrete Fe3+ ions, coordinated to pyrrolic nitrogen (N) atoms of the N-doped carbon support, that maintain their +3 oxidation state during electrocatalysis, probably through electronic coupling to the conductive carbon support. Electrochemical data suggest that the Fe3+ sites derive their superior activity from faster CO2 adsorption and weaker CO absorption than that of conventional Fe2+ sites.

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Section: E F H G Bmentioning

confidence: 78%

Atomically dispersed Fe ³⁺ sites catalyze efficient CO ₂ electroreduction to CO

Hsu

Bai

et al. 2019

Science

1,233

718

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“…Equation (26) explains the linear correlation in the region of strong adsorption (ΔG°O 2 is negative) and is essentially independent of the concentration of the reactant, in this case, O 2 .…”

Section: Mathematical Simulation Of the Variation Of Fractional Covermentioning

confidence: 95%

“…The surface coverage of active sites varies as 0 < θ M(II) < 1 depending on the electrode potential. Figure 10 shows a simulation of the variation of θ M(II) with potential using the Nernst equation for adsorbed species [26].…”

Section: Mathematical Simulation Of the Variation Of Fractional Covermentioning

confidence: 99%

“…So, Eqs. (26) and (27) describe both linear correlations in the volcano plots with slopes of different signs, i.e.+β'/RT for the strong adsorption region and Àβ'ΔG°O 2 /RT for the weak adsorption region. According to this, the volcano plot should be symmetrical since both legs of the volcano have the same absolute value of the slope.…”

Section: Mathematical Simulation Of the Variation Of Fractional Covermentioning

confidence: 99%

“…possibly for other reactions [12,13,26]. The literature in this subject is very abundant, and more details and discussion about this pyrolysed MNx catalysts are beyond the scope of this chapter.…”

Section: Linear Correlations Of E At Constant Current and (Log I) E Vmentioning

confidence: 99%

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Redox Potentials as Reactivity Descriptors in Electrochemistry

Zagal¹,

Ponce²,

Oñate³

2020

Redox

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A redox catalyst can be present in the solution phase or immobilized on the electrode surface. When the catalyst is present in the solution phase the process can proceed via inner-(with bond formation, chemical catalysis) or outer-sphere mechanisms (without bond formation, redox catalysis). For the latter, log k is linearly proportional to the redox potential of the catalysts, E°. In contrast, for inner-sphere catalyst, the values of k are much higher than those predicted by the redox potential of the catalyst. The behaviour of these catalysts when they are confined on the electrode surface is completely different. They all seem to work as inner-sphere catalysts where a crucial step is the formation of a bond between the active site and the target molecule. Plots of (log i) E versus E°give linear or volcano correlations. What is interesting in these volcano correlations is that the falling region corresponding to strong adsorption of intermediates to the active sites is not necessarily attributed to a gradual surface occupation of active sites by intermediates (Langmuir isotherm) but rather to a gradual decrease in the amount of M(II) active sites which are transformed into M(III)OH inactive sites due to the applied potential.

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Isomerism‐Activity Relation in Molecular Electrocatalysis: A Perspective

et al. 2020

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This perspective provides a brief overview on the role of isomerism of secondary‐sphere functionality in molecular electrocatalysis, without which there exists a clear knowledge‐gap in defining a molecule's structure‐activity relation. The discussion unfolds how isomerism of the functionality triggers short‐range interactions in the molecule leading to unprecedented events in electrocatalysis. This perspective highlights that the isomerism of substituents makes an independent contribution to electrocatalysis over its nature and for exploiting the maximum potential of the molecule in electrocatalysis, nature of the substituent as well as its isomerism should be given consideration.

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Probing the Fen+/Fe(n−1)+ redox potential of Fe phthalocyanines and Fe porphyrins as a reactivity descriptor in the electrochemical oxidation of cysteamine

Cited by 24 publications

References 44 publications

Atomically dispersed Fe ³⁺ sites catalyze efficient CO ₂ electroreduction to CO

Atomically dispersed Fe ³⁺ sites catalyze efficient CO ₂ electroreduction to CO

Redox Potentials as Reactivity Descriptors in Electrochemistry

Isomerism‐Activity Relation in Molecular Electrocatalysis: A Perspective

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Probing the Fen+/Fe(n−1)+ redox potential of Fe phthalocyanines and Fe porphyrins as a reactivity descriptor in the electrochemical oxidation of cysteamine

Cited by 24 publications

References 44 publications

Atomically dispersed Fe 3+ sites catalyze efficient CO 2 electroreduction to CO

Atomically dispersed Fe 3+ sites catalyze efficient CO 2 electroreduction to CO

Redox Potentials as Reactivity Descriptors in Electrochemistry

Isomerism‐Activity Relation in Molecular Electrocatalysis: A Perspective

Contact Info

Product

Resources

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Atomically dispersed Fe ³⁺ sites catalyze efficient CO ₂ electroreduction to CO

Atomically dispersed Fe ³⁺ sites catalyze efficient CO ₂ electroreduction to CO