A Redox‐Active Ligand as a Reservoir for Protons and Electrons: O<sub>2</sub> Reduction at Zirconium(IV)

Lu, Feng; Zarkesh, Ryan A.; Heyduk, Alan F.

doi:10.1002/ejic.201100798

Cited by 57 publications

(38 citation statements)

References 29 publications

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“…74 Heyduk et al explored the use of an (phenol)aminophenol ONO ligand as both electron-and proton-reservoir for the reduction of molecular oxygen with zirconium(IV). 75 Similar to the Ta mentioned in Section 2, the zirconium(IV) ion coordinates the triply deprotonated ONO trianion to form 104. However, selective deprotonation of only the phenol-groups proved facile, as the pK a values for the O-H and N-H fragments are quite different.…”

Section: (B) Ligand-centered Cooperative Reactivitymentioning

confidence: 96%

New avenues for ligand-mediated processes – expanding metal reactivity by the use of redox-active catechol, o-aminophenol and o-phenylenediamine ligands

2015

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Redox-active ligands have evolved from being considered spectroscopic curiosities - creating ambiguity about formal oxidation states in metal complexes - to versatile and useful tools to expand on the reactivity of (transition) metals or to even go beyond what is generally perceived possible. This review focusses on metal complexes containing either catechol, o-aminophenol or o-phenylenediamine type ligands. These ligands have opened up a new area of chemistry for metals across the periodic table. The portfolio of ligand-based reactivity invoked by these redox-active entities will be discussed. This ranges from facilitating oxidative additions upon d(0) metals or cross coupling reactions with cobalt(iii) without metal oxidation state changes - by functioning as an electron reservoir - to intramolecular ligand-to-substrate single-electron transfer to create a reactive substrate-centered radical on a Pd(ii) platform. Although the current state-of-art research primarily consists of stoichiometric and exploratory reactions, several notable reports of catalysis facilitated by the redox-activity of the ligand will also be discussed. In conclusion, redox-active ligands containing catechol, o-aminophenol or o-phenylenediamine moieties show great potential to be exploited as reversible electron reservoirs, donating or accepting electrons to activate substrates and metal centers and to enable new reactivity with both early and late transition as well as main group metals.

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Section: (B) Ligand-centered Cooperative Reactivitymentioning

confidence: 96%

New avenues for ligand-mediated processes – expanding metal reactivity by the use of redox-active catechol, o-aminophenol and o-phenylenediamine ligands

2015

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“…These electrochemical results also parallel those from a recent report by the Heyduk group demonstrating that it was possible to tune the redox potential of tungsten(V) complexes of a trianionic triamido ligand over a 270 mV range by changing groups along the ligand periphery without greatly altering the structures or nitrene transfer reactivity of the complexes. 11a The separation between the two oxidation potentials of the 12 Ni(X,Y) 2 complexes ranges between 200 and about 300 mV. Accordingly, the equilibrium constant for comproportionation ( K com , eq 1) varies between 10 4 and 10 6 depending on the complex, but without any obvious trend.…”

Section: Resultsmentioning

confidence: 99%

Homoleptic Nickel(II) Complexes of Redox-Tunable Pincer-type Ligands

et al. 2014

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Different synthetic methods have been developed to prepare eight new redoxactive pincer-type ligands, H(X,Y), that have pyrazol-1-yl flanking donors attached to an ortho-position of each ring of a diarylamine anchor and that have different groups, X and Y, at the para-aryl positions. Together with four previously known H(X,Y) ligands, a series of 12 Ni(X,Y)2 complexes were prepared in high yields by a simple one-pot reaction. Six of the 12 derivatives were characterized by single-crystal X-ray diffraction, which showed tetragonally distorted hexacoordinate nickel(II) centers. The nickel(II) complexes exhibit two quasireversible one-electron oxidation waves in their cyclic voltammograms, with half-wave potentials that varied over a remarkable 700 mV range with the average of the Hammett σp parameters of the para-aryl X, Y groups. The one- and two-electron oxidized derivatives [Ni(Me,Me)2](BF4)n (n = 1, 2) were prepared synthetically, were characterized by X-band EPR, electronic spectroscopy, and single-crystal X-ray diffraction (for n = 2), and were studied computationally by DFT methods. The dioxidized complex, [Ni(Me,Me)2](BF4)2, is an S = 2 species, with nickel(II) bound to two ligand radicals. The mono-oxidized complex [Ni(Me,Me)2](BF4), prepared by comproportionation, is best described as nickel(II) with one ligand centered radical. Neither the mono- nor the dioxidized derivative shows any substantial electronic coupling between the metal and their bound ligand radicals because of the orthogonal nature of their magnetic orbitals. On the other hand, weak electronic communication occurs between ligands in the mono-oxidized complex as evident from the intervalence charge transfer (IVCT) transition found in the near-IR absorption spectrum. Band shape analysis of the IVCT transition allowed comparisons of the strength of the electronic interaction with that in the related, previously known, Robin–Day class II mixed valence complex, [Ga(Me,Me)2]2+.

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“…[57] However,s trategies to effectively bridge redox non-innocence and such chemical non-innocence have been only scarcely identified to date. [58][59][60][61][62] However,i ft his selective ligand-centered hydrogen-based chemistry could be exploited alongside the established electron-based reactivity of such ligands, this might allow for interesting crossover studies between previously disparate ligand-based reactivity patterns. Ultimately,t his offers the foresight of selective and efficient proton-coupled electron transfer [63] in catalysis.I ti st herefore deemed only am atter of Scheme10.…”

Section: Discussionmentioning

confidence: 99%

Radical‐Type Reactivity and Catalysis by Single‐Electron Transfer to or from Redox‐Active Ligands

Vlugt

2018

Chemistry A European J

161

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A Redox‐Active Ligand as a Reservoir for Protons and Electrons: O₂ Reduction at Zirconium(IV)

Cited by 57 publications

References 29 publications

New avenues for ligand-mediated processes – expanding metal reactivity by the use of redox-active catechol, o-aminophenol and o-phenylenediamine ligands

New avenues for ligand-mediated processes – expanding metal reactivity by the use of redox-active catechol, o-aminophenol and o-phenylenediamine ligands

Homoleptic Nickel(II) Complexes of Redox-Tunable Pincer-type Ligands

Radical‐Type Reactivity and Catalysis by Single‐Electron Transfer to or from Redox‐Active Ligands

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A Redox‐Active Ligand as a Reservoir for Protons and Electrons: O2 Reduction at Zirconium(IV)

Cited by 57 publications

References 29 publications

New avenues for ligand-mediated processes – expanding metal reactivity by the use of redox-active catechol, o-aminophenol and o-phenylenediamine ligands

New avenues for ligand-mediated processes – expanding metal reactivity by the use of redox-active catechol, o-aminophenol and o-phenylenediamine ligands

Homoleptic Nickel(II) Complexes of Redox-Tunable Pincer-type Ligands

Radical‐Type Reactivity and Catalysis by Single‐Electron Transfer to or from Redox‐Active Ligands

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A Redox‐Active Ligand as a Reservoir for Protons and Electrons: O₂ Reduction at Zirconium(IV)