Standard Reduction Potentials for Oxygen and Carbon Dioxide Couples in Acetonitrile and <i>N</i>,<i>N</i>-Dimethylformamide

Pegis, Michael L.; Roberts, John A.; Wasylenko, Derek J.; Mader, Elizabeth A.; Appel, Aaron M.; Mayer, James M.

doi:10.1021/acs.inorgchem.5b02136

Cited by 183 publications

(221 citation statements)

References 36 publications

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“…For each of the reaction conditions used here, there is a characteristic equilibrium potential for O 2 reduction ( E O2/H2O ), depending on the solvent, proton activity, etc. 11 Similarly, each of the molecular catalysts has a characteristic redox potential under these conditions ( E Fe(III/II) ), which we approximate as the measured E 1/2 of the catalyst (see Supporting Information, page 5). We therefore define a characteristic overpotential under these conditions, η Fe/ORR = E O2/H2O – E Fe(III/II) .…”

Section: Resultsmentioning

confidence: 99%

Homogenous Electrocatalytic Oxygen Reduction Rates Correlate with Reaction Overpotential in Acidic Organic Solutions

et al. 2016

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Improved electrocatalysts for the oxygen reduction reaction (ORR) are critical for the advancement of fuel cell technologies. Herein, we report a series of 11 soluble iron porphyrin ORR electrocatalysts that possess turnover frequencies (TOFs) from 3 s–1 to an unprecedented value of 2.2 × 106 s–1. These TOFs correlate with the ORR overpotential, which can be modulated by changing the E1/2 of the catalyst using different ancillary ligands, by changing the solvent and solution acidity, and by changing the catalyst’s protonation state. The overpotential is well-defined for these homogeneous electrocatalysts by the E1/2 of the catalyst and the proton activity of the solution. This is the first such correlation for homogeneous ORR electrocatalysis, and it demonstrates that the remarkably fast TOFs are a consequence of high overpotential. The correlation with overpotential is surprising since the turnover limiting steps involve oxygen binding and protonation, as opposed to turnover limiting electron transfer commonly found in Tafel analysis of heterogeneous ORR materials. Computational studies show that the free energies for oxygen binding to the catalyst and for protonation of the superoxide complex are in general linearly related to the catalyst E1/2, and that this is the origin of the overpotential correlations. This analysis thus provides detailed understanding of the ORR barriers. The best catalysts involve partial decoupling of the influence of the second coordination sphere from the properties of the metal center, which is suggested as new molecular design strategy to avoid the limitations of the traditional scaling relationships for these catalysts.

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Section: Resultsmentioning

confidence: 99%

Homogenous Electrocatalytic Oxygen Reduction Rates Correlate with Reaction Overpotential in Acidic Organic Solutions

et al. 2016

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“…The two‐electron/two‐proton reduction of O 2 by 1,1′‐dibromoferrocene (Br 2 Fc: E ox =0.72 V vs. SCE) was catalyzed by Co II (Ch), whereas virtually no reduction of O 2 by Br 2 Fc occurred with Co II (OEP) in the presence of HClO 4 (25 m m ) in PhCN at 298 K . Because the standard reduction potential of O 2 to H 2 O in MeCN is reported to be 1.21 V vs. Fc + /Fc, the standard reduction potential of O 2 to H 2 O 2 in MeCN is evaluated to be 0.56 V vs. Fc + /Fc, based on the difference in the standard reduction potential of O 2 to H 2 O (1.23 V vs. SHE) and that of O 2 to H 2 O 2 (0.68 V vs. SHE) . Then, the reduction potential of O 2 to H 2 O 2 in the presence of HClO 4 (25 m m ) in PhCN is estimated to be 0.47 V vs. Fc + /Fc in MeCN, because the difference in concentration of H + (25 m m and 1.0 m ) results in a difference in the reduction potential of 0.09 V. In such case, the reduction of O 2 to H 2 O 2 ( E 0 ′=0.47 V vs. Fc + /Fc) with Br 2 Fc (0.72 V vs. SCE=0.35 V vs. Fc + /Fc) is thermodynamically feasible with a small overpotential (0.12 V).…”

Section: Cobalt Complex Catalystsmentioning

confidence: 99%

“…The standard redox potential of the four‐electron reduction of O 2 with four protons to water under the standard conditions of aqueous acid with unit activity (pH 0), an oxygen pressure of 1 atm and at 25 °C is 1.229 V referenced to the standard hydrogen electrode (SHE) [Eq. ]

true normalO_{2} + 4 normale^{-} + 4 H^{+} \to 2 normalH_{2} normalO E_{0} = 1.229 normalV vs . SHE

…”

Section: Introductionmentioning

confidence: 99%

Mechanisms of Two‐Electron versus Four‐Electron Reduction of Dioxygen Catalyzed by Earth‐Abundant Metal Complexes

2017

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The two‐electron reduction of dioxygen with two protons produces hydrogen peroxide, which is directly used as a liquid fuel in hydrogen peroxide fuel cells, whereas the four‐electron reduction of dioxygen is combined with the two‐electron oxidation of hydrogen in hydrogen fuel cells. Platinum (Pt)‐based nanocomposites are the most efficient commercial electrocatalysts for the oxygen reduction reaction (ORR). However, the poor stability, scarcity and high cost of these Pt‐based oxygen electrocatalysts are major barriers for the large‐scale implementation of fuel cell technologies. Replacing noble metal‐based electrocatalysts with highly efficient and inexpensive earth‐abundant metal‐based oxygen electrocatalysts has been of critical importance for practical applications. To develop efficient catalysts for the two‐electron and four‐electron reduction of dioxygen, it is crucially important to clarify the catalytic mechanisms of two‐electron/two‐proton versus four‐electron/four‐proton reduction of dioxygen with earth‐abundant metal complexes. This review focused on the factors that control the two‐electron/two‐proton versus four‐electron/four‐proton reduction of dioxygen by electron donors (one electron reductants) such as ferrocene, catalyzed by earth‐abundant metal complexes such as iron, cobalt, copper, manganese and nickel complexes in the homogeneous phase, by detecting catalytic intermediates, which determine the catalytic pathways of the two‐electron versus four‐electron reduction of dioxygen. The electrocatalytic two‐electron or/and four‐electron reduction of dioxygen with earth‐abundant metal complexes and metal oxides has also been discussed in relation with the homogeneous catalysis.

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“…For C c O, or for a given efficient molecular catalyst able to promote four-electron, four-proton O 2 -reduction to water ( E ° MeCN = 1.21 V vs Fc +/0 ), 47 these particular nuances relevant to the promotion of the O–O cleavage process need to be delineated and understood within the framework of reduction/protonation chemistry. The breadth of these PCET studies involves probing different (or perhaps simultaneous) orderings of the events of (i) electron transfer (from Fe, Cu, or the Tyr phenol moiety), and (ii) proton transfer derived from different sources.…”

Section: Introductionmentioning

confidence: 99%

Critical Aspects of Heme–Peroxo–Cu Complex Structure and Nature of Proton Source Dictate Metal–O_peroxo Breakage versus Reductive O–O Cleavage Chemistry

et al. 2016

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The 4H+/4e− reduction of O2 to water, a key fuel-cell reaction also carried out in biology by oxidase enzymes, includes the critical O–O bond reductive cleavage step. Mechanistic investigations on active-site model compounds, which are synthesized by rational design to incorporate systematic variations, can focus on and resolve answers to fundamental questions, including protonation and/or H-bonding aspects, which accompany electron transfer. Here, we describe the nature and comparative reactivity of two low-spin heme–peroxo–Cu complexes, LS-4DCHIm, [(DCHIm)F8FeIII-(O22−)-CuII(DCHIm)4]+, and LS-3DCHIm, [(DCHIm)F8FeIII-(O22−)-CuII(DCHIm)3]+ (F8 = tetrakis(2,6-difluorophenyl)-porphyrinate; DCHIm = 1,5-dicyclohexylimidazole), toward different proton (4-nitrophenol and [DMF·H+](CF3SO3−)) (DMF = dimethylformamide) or electron (decamethylferrocene (Fc*)) sources. Spectroscopic reactivity studies show that differences in structure and electronic properties of LS-3DCHIm and LS-4DCHIm lead to significant differences in behavior. LS-3DCHIm is resistant to reduction, is unreactive toward weakly acidic 4-NO2–phenol, and stronger acids cleave the metal–O bonds, releasing H2O2. By contrast, LS-4DCHIm forms an adduct with 4-NO2–phenol, which includes an H-bond to the peroxo O-atom distal to Fe (resonance Raman (rR) spectroscopy and DFT). With addition of Fc* (2 equiv overall required), O–O reductive cleavage occurs, giving water, Fe(III), and Cu(II) products; however, a kinetic study reveals a one-electron rate-determining process, ket = 1.6 M−1 s−1 (−90 °C). The intermediacy of a high-valent [(DCHIm)F8FeIV = O] species is thus implied, and separate experiments show that one-electron reduction-protonation of [(DCHIm)F8FeIV=O] occurs faster (ket2 = 5.0 M−1 s−1), consistent with the overall postulated mechanism. The importance of the H-bonding interaction as a prerequisite for reductive cleavage is highlighted.

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Standard Reduction Potentials for Oxygen and Carbon Dioxide Couples in Acetonitrile and N,N-Dimethylformamide

Cited by 183 publications

References 36 publications

Homogenous Electrocatalytic Oxygen Reduction Rates Correlate with Reaction Overpotential in Acidic Organic Solutions

Homogenous Electrocatalytic Oxygen Reduction Rates Correlate with Reaction Overpotential in Acidic Organic Solutions

Mechanisms of Two‐Electron versus Four‐Electron Reduction of Dioxygen Catalyzed by Earth‐Abundant Metal Complexes

Critical Aspects of Heme–Peroxo–Cu Complex Structure and Nature of Proton Source Dictate Metal–O_peroxo Breakage versus Reductive O–O Cleavage Chemistry

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Standard Reduction Potentials for Oxygen and Carbon Dioxide Couples in Acetonitrile and N,N-Dimethylformamide

Cited by 183 publications

References 36 publications

Homogenous Electrocatalytic Oxygen Reduction Rates Correlate with Reaction Overpotential in Acidic Organic Solutions

Homogenous Electrocatalytic Oxygen Reduction Rates Correlate with Reaction Overpotential in Acidic Organic Solutions

Mechanisms of Two‐Electron versus Four‐Electron Reduction of Dioxygen Catalyzed by Earth‐Abundant Metal Complexes

Critical Aspects of Heme–Peroxo–Cu Complex Structure and Nature of Proton Source Dictate Metal–Operoxo Breakage versus Reductive O–O Cleavage Chemistry

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Critical Aspects of Heme–Peroxo–Cu Complex Structure and Nature of Proton Source Dictate Metal–O_peroxo Breakage versus Reductive O–O Cleavage Chemistry