Concerted Proton–Electron Transfer Reactivity at a Multimetallic Co<sub>4</sub>O<sub>4</sub> Cubane Cluster

Amtawong, Jaruwan; Skjelstad, Bastian Bjerkem; Balcells, David; Tilley, T. Don

doi:10.1021/acs.inorgchem.0c02625

Cited by 20 publications

(33 citation statements)

References 67 publications

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“…Significantly, electronic changes at the ligand set are transmitted through all three Co centers to the Ru–oxo moiety, indicating that the metal centers are working cooperatively as an assembly in oxidizing C–H substrates. Similar multimetallic cooperative effects have been predicted by DFT in the C–H activation study of the related Co 4 O 4 cubane . These studies indicate a direct influence of the electronic communication within the cubane clusters on C–H activation reactivity.…”

Section: Resultssupporting

confidence: 78%

“…Similar multimetallic cooperative effects have been predicted by DFT in the C−H activation study of the related Co 4 O 4 cubane. 18 These studies indicate a direct influence of the electronic communication within the cubane clusters on C−H activation reactivity.…”

Section: ■ Results and Discussionmentioning

confidence: 90%

“…While significant efforts have elucidated the mechanisms of metal–oxo mediated PCET reactions, − a limited subset of these studies employ high-valent multimetallic-oxo complexes. − Indeed, reactive multimetallic-oxo species bearing well-characterized terminal metal–oxo/oxyl motifs are exceedingly rare despite their importance as key intermediates in oxidative catalysis. ,,− To date, few spectroscopically and computationally characterized high-valent multimetallic-oxo/oxyl species exist . Meyer and co-workers have provided evidence for a dioxo–Ru V intermediate, [(bpy) 2 (O)Ru V ORu V (O)(bpy) 2 ] 4+ (bpy = 2,2′-bipyridine), derived from PCET reactions of the binuclear oxo “blue dimer” [(bpy) 2 (H 2 O)Ru III ORu III (H 2 O)(bpy) 2 ] 4+ (Scheme c). − This dioxo–Ru V intermediate appears to possess considerable spin density at the terminal oxo ligands, and a radical coupling between the two terminal Ru V –oxo moieties has been proposed to mediate O–O bond formation. , Indeed, transient intermediate Ru V –oxo species are commonly invoked in water and organic oxidation catalysis. − Although metal–oxyl species are known to exhibit unique reactivity, it is unclear how the spin density localized on oxo ligands contributes to the PCET reactivity of multimetallic-oxo clusters. , Studies of high-valent multimetallic-oxo clusters bearing terminal oxo/oxyl moieties present an opportunity to probe the influence of metal–metal cooperativity and provide insight into the role of oxyl radical character in PCET reactions.…”

Section: Introductionmentioning

confidence: 99%

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C–H Activation by RuCo₃O₄ Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

et al. 2021

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High-valent multimetallic-oxo/oxyl species have been implicated as intermediates in oxidative catalysis involving proton-coupled electron transfer (PCET) reactions, but the reactive nature of these oxo species has hindered the development of an in-depth understanding of their mechanisms and multimetallic character. The mechanism of C–H oxidation by previously reported RuCo3O4 cubane complexes bearing a terminal RuV–oxo ligand, with significant oxyl radical character, was investigated. The rate-determining step involves H atom abstraction (HAA) from an organic substrate to generate a Ru–OH species and a carbon-centered radical. Radical intermediates are subsequently trapped by another equivalent of the terminal oxo to afford isolable radical-trapped cubane complexes. Density functional theory (DFT) reveals a barrierless radical combination step that is more favorable than an oxygen-rebound mechanism by 12.3 kcal mol–1. This HAA reactivity to generate organic products is influenced by steric congestion and the C–H bond dissociation energy of the substrate. Tuning the electronic properties of the cubane (i.e., spin density localized on terminal oxo, basicity, and redox potential) by varying the donor ability of ligands at the Co sites modulates C–H activations by the RuV–oxo fragment and enables construction of structure–activity relationships. These results reveal a mechanistic pathway for C–H activation by high-valent metal–oxo species with oxyl radical character and provide insights into cooperative effects of multimetallic centers in tuning PCET reactivity.

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Section: Resultssupporting

confidence: 78%

Section: ■ Results and Discussionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

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C–H Activation by RuCo₃O₄ Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

et al. 2021

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“…In both examples, the BDFE(O–H) of the bridging hydroxide ligands of the resultant 2e – /2H + reduced assembly are greater than 71 kcal/mol, on the basis of the reactivity of these complexes with sacrificial hydrogen atom donors with well-established BDFEs. Seminal work from Tilley and co-workers describes the BDFE(O–H) of a μ 2 –OH moiety embedded in a cobalt oxide cubane (74 kcal/mol) . In all cases, the experimentally established BDFE(O–H) values of the polynuclear metal oxide clusters are significantly larger (>10 kcal/mol) than that of complex V 6 O 7 (OH) 6 .…”

Section: Resultsmentioning

confidence: 97%

Concerted Multiproton–Multielectron Transfer for the Reduction of O₂ to H₂O with a Polyoxovanadate Cluster

et al. 2021

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The concerted transfer of protons and electrons enables the activation of small-molecule substrates by bypassing energetically costly intermediates. Here, we present the synthesis and characterization of several hydrogenated forms of an organofunctionalized vanadium oxide assembly, [V 6 O 13 (TRIOL NO 2 ) 2 ] 2− , and their ability to facilitate the concerted transfer of protons and electrons to O 2 . Electrochemical analysis reveals that the fully reduced cluster is capable of mediating 2e − /2H + transfer reactions from surface hydroxide ligands, with an average bond dissociation free energy (BDFE) of 61.6 kcal/mol. Complementary stoichiometric experiments with hydrogen-atom-accepting reagents of established bond strengths confirm that the electrochemically established BDFE predicts the 2H + /2e − transfer reactivity of the assembly. Finally, the reactivity of the reduced polyoxovanadate toward O 2 reduction is summarized; our results indicate a stepwise reduction of the substrate, proceeding through H 2 O 2 en route to the formation of H 2 O. Kinetic isotope effect experiments confirm the participation of hydrogen transfer in the rate-determining step of both the reduction of O 2 and H 2 O 2 . This work constitutes the first example of hydrogen atom transfer for small-molecule activation with reduced polyoxometalates, where both electron and proton originate from the cluster.

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“…21,22 There are only a few examples of metal-oxide and -chalcogenide clusters that are catalytically active, including [Mo3S13] 2and [MoFe3(µ3-S)4], for hydrogen evolution and hydrazine reduction, 23,24 respectively, and the cubane-type cluster [Co4(µ3-O)4], for catalytic C-H activation and water oxidation. 25,26 In contrast, metal clusters, particularly of gold, can catalyze a wide range of reactions. 27,28 However, in part due to scalability challenges, the elucidation of catalytic intermediates remains challenging and relies heavily on computational modeling.…”

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confidence: 99%

Multi-active Site Dynamics on a Molecular Cr/Co/Se Cluster Catalyst

Kephart

Mitchell

Kaminsky

et al. 2022

Preprint

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This study provides detailed insights into the interconnected reactivity of the three catalytically active sites of an atomically precise nanocluster Cr3(py)3Co6Se8L6 (Cr3(py)3, L = Ph2PNTol–, Ph = phenyl, Tol = 4-tolyl). Catalytic and stoichiometric studies into tosyl azide activation and carbodiimide formation enabled the isolation and crystallographic characterization of key metal-nitrenoid catalytic intermediates, including the tris(nitrenoid) cluster Cr3(NTs)3, the catalytic resting state Cr3(NTs)3(CNtBu)3, and the mono(nitrenoid) cluster Cr3(NTs)(CNtBu)2. Nitrene transfer proceeds via a stepwise mechanism, with the three active sites engaging sequentially to produce carbodiimide. Comparative structural analysis and CNtBu bind-ing studies reveal that the chemical state of neighboring active sites regulates the affinity for substrates of an individual Cr-nitrenoid edge site, intertwining their reactivity through the inorganic support.

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Concerted Proton–Electron Transfer Reactivity at a Multimetallic Co₄O₄ Cubane Cluster

Cited by 20 publications

References 67 publications

C–H Activation by RuCo₃O₄ Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

C–H Activation by RuCo₃O₄ Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

Concerted Multiproton–Multielectron Transfer for the Reduction of O₂ to H₂O with a Polyoxovanadate Cluster

Multi-active Site Dynamics on a Molecular Cr/Co/Se Cluster Catalyst

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Concerted Proton–Electron Transfer Reactivity at a Multimetallic Co4O4 Cubane Cluster

Cited by 20 publications

References 67 publications

C–H Activation by RuCo3O4 Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

C–H Activation by RuCo3O4 Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

Concerted Multiproton–Multielectron Transfer for the Reduction of O2 to H2O with a Polyoxovanadate Cluster

Multi-active Site Dynamics on a Molecular Cr/Co/Se Cluster Catalyst

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Product

Resources

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Concerted Proton–Electron Transfer Reactivity at a Multimetallic Co₄O₄ Cubane Cluster

C–H Activation by RuCo₃O₄ Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

C–H Activation by RuCo₃O₄ Oxo Cubanes: Effects of Oxyl Radical Character and Metal–Metal Cooperativity

Concerted Multiproton–Multielectron Transfer for the Reduction of O₂ to H₂O with a Polyoxovanadate Cluster