How Metal Ion Lewis Acidity and Steric Properties Influence the Barrier to Dioxygen Binding, Peroxo O–O Bond Cleavage, and Reactivity

Poon, Penny Chaau Yan; Dedushko, Maksym A.; Sun, Xian-Ru; Yang, Guang; Toledo, Santiago; Hayes, Ellen C.; Johansen, A. R.; Piquette, Marc C.; Rees, Julian A.; Stoll, Stefan; Rybak‐Akimova, Elena V.; Kovacs, Julie A.

doi:10.1021/jacs.9b04729

Cited by 17 publications

(7 citation statements)

References 64 publications

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“…These recent studies suggest that there is a continuing benefit to the study of the molecular electrocatalytic reduction of O 2 . The mechanistic fundamentals of homogeneous O 2 activation have relevance to the understanding of biological systems, as well as the development of better ORR and aerobic oxidation catalysts. ,− There is sustained interest in running the latter electrochemically, − given the obvious parallels to the function of Cytochrome P450, − which catalyzes the oxygenation of endogenous and exogenous molecules to produce important metabolites. Mechanistic and thermodynamic understanding of molecular catalysis can be the basis of intriguing systems with careful experimental design: a recent study combined Rh porphyrins with methane and O 2 to assemble an abiotic system capable of activity analogous to methane monooxygenase by exploiting electrochemically generated reaction gradients created by inorganic nanomaterials .…”

Section: Discussionmentioning

confidence: 99%

Advances in the Molecular Catalysis of Dioxygen Reduction

Machan

2020

ACS Catal.

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The reduction of dioxygen (O2) is of vital importance to energy-related reactions. In biology, respiration uses O2 reduction as a thermodynamic sink, whereas fuel cells pair the oxygen reduction reaction (ORR) to H2O as a proton-dependent half-reaction to the oxidation of chemical fuels. Catalytic ORR processes mediated by molecular inorganic species continue to garner interest as models for heterogeneous systems. The ability to directly observe, quantify, and synthesize relevant intermediates from proposed reaction mechanisms renders molecular species readily optimizable, relative to the distribution of active sites within the nanoscale and mesoscale morphologies of heterogeneous systems. The development of next-generation cathode materials to displace platinum (Pt) for ORR will require improvements in the fundamental understanding of how O2 behaves as a substrate, which well-defined homogeneous systems are uniquely positioned to provide. This Perspective provides a summary of recent advances in the area of homogeneous catalytic O2 reduction, with a particular emphasis on improvements in activity and selectivity aided by mechanistic understanding.

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Section: Discussionmentioning

confidence: 99%

Advances in the Molecular Catalysis of Dioxygen Reduction

Machan

2020

ACS Catal.

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“…We note that the stoichiometric chemistry of Mn complexes with thiolate containing ligands and O 2 has been explored extensively by Kovacs and coworkers. [71][72][73][74][75] Upon exposure to dry air, both centers were oxidized by a single electron and a bridging hydroxide species was recovered. Mechanistic studies established that the dinuclear monothiol species united two separate reaction cycles, where either H 2 O 2 or H 2 O production was favored.…”

Section: Catalytic O 2 Reduction Mediated By Mnmentioning

confidence: 99%

“…13D and F). 74,122 6. Critical analysis of homogeneous ORR by molecular Mn/Fe/Co Extensive studies on the ORR mediated by metalloporphyrins allows for a critical comparison of activity and mechanism for structurally analogous systems containing Fe, Co and Mn active sites.…”

Section: àmentioning

confidence: 99%

Homogeneous catalysis of dioxygen reduction by molecular Mn complexes

Cook

Machan

2022

Chem. Commun.

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“…Much of our understanding of the properties of heme and nonheme iron enzyme dioxygen intermediates such as Fe(III)–superoxos, Fe(III)–peroxos, and high-valent iron oxos comes from small-molecule chemistry. − Only a small number of these are derived from O 2 , ,− and despite the key role of thiolates in a wide variety of nonheme iron enzymes, only a small number of these contain thiolates in the coordination sphere. ,,, Key properties unique to aliphatic thiolate (RS – or Cys-S – ) ligands include an increase in the potency of high-valent iron oxo intermediates − and, as shown by our group, the potency of iron-superoxo compounds with respect to their ability to cleave strong C–H bonds. , We also recently showed that aliphatic thiolates help to promote peroxo O–O bond cleavage. , Very few well-characterized iron-superoxo compounds have been reported, ,− and of those reported, only two incorporate a thiolate in the coordination sphere , and only one cleaves strong C–H bonds . We recently showed that aliphatic thiolate-ligated [Fe II (S 2 Me2 N 3 (Pr,Pr))] ( 1 ) reacts with O 2 (Scheme ) to form an unprecedented example of an aliphatic thiolate-ligated iron superoxo intermediate, [Fe III (S 2 Me2 N 3 (Pr,Pr))(O 2 )] ( 2 ), which is capable of cleaving strong C–H bonds (e.g., tetrahydrofuran (THF) (BDE(C–H) = 92 kcal mol –1 )) at −73 °C with a k H / k D = 4.8 .…”

Section: Introductionmentioning

confidence: 99%

Electronic Structure and Reactivity of Dioxygen-Derived Aliphatic Thiolate-Ligated Fe-Peroxo and Fe(IV) Oxo Compounds

et al. 2022

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Herein, we examine the electronic and geometric structural properties of O2-derived aliphatic thiolate-ligated Fe-peroxo, Fe-hydroxo, and Fe(IV) oxo compounds. The latter cleaves strong C–H bonds (96 kcal mol–1) on par with the valine C–H bond cleaved by isopencillin N synthase (IPNS). Stopped-flow kinetics studies indicate that the barrier to O2 binding to [FeII(SMe2N4(tren))]+ (3) is extremely low (E a = 36(2) kJ mol–1), as theoretically predicted for IPNS. Dioxygen binding to 3 is shown to be reversible, and a superoxo intermediate, [FeIII(SMe2N4(tren))(O2)]+ (6), forms in the first 25 ms of the reaction at −40 °C prior to the rate-determining (E a = 46(2) kJ mol–1) formation of peroxo-bridged [(SMe2N4(tren))Fe(III)]2(μ-O2)2+ (7). A log(k obs) vs log([Fe]) plot for the formation of 7 is consistent with the second-order dependence on iron, and H2O2 assays are consistent with a 2:1 ratio of Fe/H2O2. Peroxo 7 is shown to convert to ferric-hydroxo [FeIII(SMe2N(tren))(OH)]+ (9, g ⊥ = 2.24, g ∥ = 1.96), the identity of which was determined via its independent synthesis. Rates of the conversion 7 → 9 are shown to be dependent on the X–H bond strength of the H-atom donor, with a k H/k D = 4 when CD3OD is used in place of CH3OH as a solvent. A crystallographically characterized cis thiolate-ligated high-valent iron oxo, [FeIV(O)(SMe2N4(tren))]+ (11), is shown to form en route to hydroxo 9. Electronic structure calculations were shown to be consistent with 11 being an S = 1 Fe(IV)O with an unusually high ν Fe–O stretching frequency at 918 cm–1 in line with the extremely short Fe–O bond (1.603(7) Å).

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How Metal Ion Lewis Acidity and Steric Properties Influence the Barrier to Dioxygen Binding, Peroxo O–O Bond Cleavage, and Reactivity

Cited by 17 publications

References 64 publications

Advances in the Molecular Catalysis of Dioxygen Reduction

Advances in the Molecular Catalysis of Dioxygen Reduction

Homogeneous catalysis of dioxygen reduction by molecular Mn complexes

Electronic Structure and Reactivity of Dioxygen-Derived Aliphatic Thiolate-Ligated Fe-Peroxo and Fe(IV) Oxo Compounds

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