Reexamining Oxidation States during the Synthesis of 2-Rhodaoxetanes from Olefins

Desnoyer, Addison N.; Behyan, Shirin; Patrick, Brian O.; Dauth, Alexander; Love, Jennifer A.; Kennepohl, Pierre

doi:10.1021/acs.inorgchem.5b02703

Cited by 13 publications

(17 citation statements)

References 35 publications

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“…Based on literature precedent, the reduction of Rh III to Rh I is expected to shift the rising portion of the K-edge to lower energy by 2-3 eV. 19,20 Indeed, we observe a significant difference in both the position and shape of the K-edge between [Rh III Cp*(phen)Cl] + and Rh I Cp*(phen) ( Figure S20). The Rh K-edge for [Rh III Cp*(phen)Cl] + has an inflection point at 23,226.5 eV, while the Rh K-edge for Rh I Cp*(phen) onsets earlier and has two inflection points at 23,225.6 and 23,231.7 eV ( Figure S21).…”

Section: Electrochemistry and X-ray Absorption Spectroscopy Of Gcc-rhsupporting

confidence: 59%

Strong Electronic Coupling of Molecular Sites to Graphitic Electrodes via Pyrazine Conjugation

et al. 2018

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Glassy carbon electrodes were functionalized with redox-active moieties by condensation of o-phenylenediamine derivatives with o-quinone sites native to graphitic carbon surfaces. Electrochemical and spectroscopic investigations establish that these graphite-conjugated catalysts (GCCs) exhibit strong electronic coupling to the electrode, leading to electron transfer (ET) behavior that diverges fundamentally from that of solution-phase or surface-tethered analogues. We find that (1) ET is not observed between the electrode and a redox-active GCC moiety regardless of applied potential. (2) ET is observed at GCCs only if the interfacial reaction is ion-coupled. (3) Even when ET is observed, the oxidation state of a transition metal GCC site remains unchanged. From these observations, we construct a mechanistic model for GCC sites in which ET behavior is identical to that of catalytically active metal surfaces rather than to that of molecules in solution. These results suggest that GCCs provide a versatile platform for bridging molecular and heterogeneous electrocatalysis.

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Section: Electrochemistry and X-ray Absorption Spectroscopy Of Gcc-rhsupporting

confidence: 59%

Strong Electronic Coupling of Molecular Sites to Graphitic Electrodes via Pyrazine Conjugation

et al. 2018

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“…Experimentally,t he 31 P{ 1 H} NMR spectrum of 1 up to 110 8Cr eveals no dynamic processes, indicatingt hat the barrier to carbonyl rotation is greater than 70 kJ mol À1 .W eh ave previously reported similar high barriers to rotation with ar hodium-olefin system. [8] Indeed, the metallaepoxide electromer of related nickel complexes have recently been invoked by the groups of Doyle [42] and Ogoshi [37] based on reactivity studies, andi sa lso shown explicitly in Group 4c omplexes that display similars tructural parameters to the nickel species discussed here. [58][59][60][61][62][63] Ambiguity in the electronic structureo ft hese nickel p-complexesh inderse fforts towards the rational design of nickel-catalysed processes.…”

Section: Introductionmentioning

confidence: 79%

“…[87] Given that the electron density of these systems are well described from DFTcalculations, we approached this same issue by applying natural resonance theory (NRT) [109][110][111] to expose different contributions to the overall electronic description ( Table 5). [8] In all cases, the Ni II metallacycle contributesl ittle to the overall electronic structure. TheN i 0 p-adduct and Ni I intermediate resonance structures account for > 80 %o ft he electronic structure in all cases.…”

Section: Discussionmentioning

confidence: 99%

“…In previous work, we noted that the 31 P{ 1 H} NMR spectroscopic data of an umber of (dtbpe)Ni [dtbpe = 1,2-bis(di-tertbutyl)phosphinoethane] p-complexes werec onsistent with typical d 10 Ni 0 complexes (Table 1). [10,11,57] In contrast, we also noted that the distorted squarep lanar geometry with significant elongation of the p-bond was mostc onsistentw ith ad 8 Ni II formulation,i nk eeping with the metallaepoxide extreme of the Dewar-Chatt-Duncanson (DCD) model of bonding (Scheme 1). In addition, preliminaryd ensity functional theory (DFT) calculations (vide infra) revealed prohibitively high barriers to rotationo ft he p-ligand (i.e.,8 0-100 kJ mol À1 ), demonstratingt hat these complexes have as trong preference for the square planar geometry despite stericc onstraints.…”

Section: Introductionmentioning

confidence: 88%

“…[5] In contrast to these open-shell systems, closed-shell systems that rely on the ligand-accepting and/or-donating electron pairs are less common.Anotable example of this type of reactivity is the zirconium system reported by Heyduk, which allowsf or ap utative "oxidativea ddition" reaction to occur at a Zr IV ,d 0 metal centre. [6] In another example, we have recently shownt hat the oxidation of (TPA)Rh olefin complexes (TPA = tris(2-pyridylmethyl)amine) with H 2 O 2 to form 2-rhodaoxetanes [7] is more accurately described as al igand-centred [8] rather than metal-centred oxidation. [9] In this case, the p-ligand acts as at wo-electron redoxcentre.…”

Section: Introductionmentioning

confidence: 99%

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The Importance of Ligand‐Induced Backdonation in the Stabilization of Square Planar d¹⁰ Nickel π‐Complexes

Desnoyer

Behyan

et al. 2019

Chemistry A European J

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The electronic nature of Ni π‐complexes is underexplored even though these complexes have been widely postulated as intermediates in organometallic chemistry. Herein, the geometric and electronic structure of a series of nickel π‐complexes, Ni(dtbpe)(X) (dtbpe=1,2‐bis(di‐tert‐butyl)phosphinoethane; X=alkene or carbonyl containing π‐ligands), is probed using a combination of 31P NMR, Ni K‐edge XAS, Ni Kβ XES, and DFT calculations. These complexes are best described as square planar d10 complexes with π‐backbonding acting as the dominant contributor to M−L bonding to the π‐ligand. The degree of backbonding correlates with 2JPP from NMR and the energy of the Ni 1s→4pz pre‐edge in the Ni K‐edge XAS data, and is determined by the energy of the π*ip ligand acceptor orbital. Thus, unactivated olefinic ligands tend to be poor π‐acids whereas ketones, aldehydes, and esters allow for greater backbonding. However, backbonding is still significant even in cases in which metal contributions are minor. In such cases, backbonding is dominated by charge donation from the diphosphine, which allows for strong backdonation, although the metal centre retains a formal d10 electronic configuration. This ligand‐induced backbonding can be formally described as a 3‐centre‐4‐electron (3c‐4e) interaction, in which the nickel centre mediates charge transfer from the phosphine σ‐donors to the π*ip ligand acceptor orbital. The implications of this bonding motif are described with respect to both structure and reactivity.

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Activating a Peroxo Ligand for C−O Bond Formation

et al. 2019

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Dioxygen activation for effective C−O bond formation in the coordination sphere of a metal is a long standing challenge in chemistry for which the design of catalysts for oxygenations is slowed down by the complicated −sometimes poorly understood− mechanistic panorama. In this context, olefin-peroxide complexes could be valuable models for the study of such reactions. Herein, we showcase the isolation of rare 'Ir(cod)(peroxide)' complexes (cod =1,5-cyclooctadiene) from reactions with oxygen, and then the activation of the peroxide ligand for O−O bond cleavage and C−O bond formation by transfer of a hydrogen atom through PT/ET reactions to give 2-iradaoxetane complexes and water. 2,4, 1, and 1,cyclohexadiene were used as hydrogen atom donors. These reactions can be key steps in the oxy-functionalization of olefins with oxygen and they constitute a novel mechanistic pathway disclosed for iridium whose full reaction profile is supported by DFT-calculations.

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Reexamining Oxidation States during the Synthesis of 2-Rhodaoxetanes from Olefins

Cited by 13 publications

References 35 publications

Strong Electronic Coupling of Molecular Sites to Graphitic Electrodes via Pyrazine Conjugation

Strong Electronic Coupling of Molecular Sites to Graphitic Electrodes via Pyrazine Conjugation

The Importance of Ligand‐Induced Backdonation in the Stabilization of Square Planar d¹⁰ Nickel π‐Complexes

Activating a Peroxo Ligand for C−O Bond Formation

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Reexamining Oxidation States during the Synthesis of 2-Rhodaoxetanes from Olefins

Cited by 13 publications

References 35 publications

Strong Electronic Coupling of Molecular Sites to Graphitic Electrodes via Pyrazine Conjugation

Strong Electronic Coupling of Molecular Sites to Graphitic Electrodes via Pyrazine Conjugation

The Importance of Ligand‐Induced Backdonation in the Stabilization of Square Planar d10 Nickel π‐Complexes

Activating a Peroxo Ligand for C−O Bond Formation

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Product

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The Importance of Ligand‐Induced Backdonation in the Stabilization of Square Planar d¹⁰ Nickel π‐Complexes