Reaction of Molecular Oxygen with a Pd<sup>II</sup>– Hydride To Produce a Pd<sup>II</sup>–Hydroperoxide: Acid Catalysis and Implications for Pd‐Catalyzed Aerobic Oxidation Reactions

Konnick, Michael M.; Gandhi, Bhavesh A.; Guzei, Ilia A.; Stahl, Shannon S.

doi:10.1002/anie.200600532

Cited by 150 publications

(86 citation statements)

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“…[65] Studies of O 2 insertion into Pd II ÀH bonds in non-pincerligated systems by Stahl et al revealed a different mechanism. [66][67][68][69] In this case, initial reductive elimination of HX from the Pd II hydride complex to generate a Pd 0 species (Scheme 8) is followed by reaction of the Pd 0 with O 2 to form an h 2 -peroxo complex (as described above). The Pd II -(h 2 -peroxo) is then protonated to generate the observed PdÀOOH moiety.…”

Section: Formal Insertion Of O 2 Into Pd II àH Bondsmentioning

confidence: 99%

Reactions of Pd and Pt Complexes with Molecular Oxygen

Scheuermann

Goldberg

2014

Chemistry A European J

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Knowledge of exactly how metal complexes react with molecular oxygen is still limited and this has hampered efforts to develop catalysts for oxidation reactions using O2 as the oxidant and/or oxygen-atom source. A better understanding of the reactions of different types of metal complexes with O2 will be of great utility in rational catalyst development. Reactions between molecular oxygen and Pd(0-II) and Pt(0-IV) complexes are reviewed here.

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Section: Formal Insertion Of O 2 Into Pd II àH Bondsmentioning

confidence: 99%

Reactions of Pd and Pt Complexes with Molecular Oxygen

Scheuermann

Goldberg

2014

Chemistry A European J

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“…As shown in Table 1 (entries 1 and 2), in the presence of 2 mol % [Pd(OAc) 2 ] without any ligand only the well-known oxidation towards benzaldehyde occurred in fair yield. [13] Using methanol as solvent and adding K 2 CO 3 as base led to some cross-esterification product (43 % methyl benzoate). However, the reaction proceeded in a nonselective manner and the catalyst immediately turned black ( Table 1, entries [3][4].…”

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confidence: 99%

General and Selective Palladium‐Catalyzed Oxidative Esterification of Alcohols

2011

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“…4−13 Insertion of O 2 into metal hydride bonds is often a key step in its activation, and metal hydroperoxide complexes are frequently the observed products of this reaction. Indeed, such reactions have been observed for hydride complexes of cobalt, 14 iridium, 15 palladium, 16,17 platinum, 18,19 and rhodium. 20−23 Accordingly, studies of the reaction of O 2 with metal hydride complexes are germane to expanding the scope and utility of aerobic oxidation reactions.…”

Section: ■ Introductionmentioning

confidence: 94%

Oxygen Reduction Mechanism of Monometallic Rhodium Hydride Complexes

2015

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The reduction of O2 to H2O mediated by a series of electronically varied rhodium hydride complexes of the form cis,trans-Rh(III)Cl2H(CNAd)(P(4-X-C6H4)3)2 (2) (CNAd = 1-adamantylisocyanide; X = F (2a), Cl (2b), Me (2c), OMe (2d)) was examined through synthetic and kinetic studies. Rhodium(III) hydride 2 reacts with O2 to afford H2O with concomitant generation of trans-Rh(III)Cl3(CNAd)(P(4-X-C6H4)3)2 (3). Kinetic studies of the reaction of the hydride complex 2 with O2 in the presence of HCl revealed a two-term rate law consistent with an HX reductive elimination (HXRE) mechanism, where O2 binds to a rhodium(I) metal center and generates an η(2)-peroxo complex intermediate, trans-Rh(III)Cl(CNAd)(η(2)-O2)(P(4-X-C6H4)3)2 (4), and a hydrogen-atom abstraction (HAA) mechanism, which entails the direct reaction of O2 with the hydride. Experimental data reveal that the rate of reduction of O2 to H2O is enhanced by electron-withdrawing phosphine ligands. Complex 4 was independently prepared by the addition of O2 to trans-Rh(I)Cl(CNAd)(P(4-X-C6H4)3)2 (1). The reactivity of 4 toward HCl reveals that such peroxo complexes are plausible intermediates in the reduction of O2 to H2O. These results show that the given series of electronically varied rhodium(III) hydride complexes facilitate the reduction of O2 to H2O according to a two-term rate law comprising HXRE and HAA pathways and that the relative rates of these two pathways, which can occur simultaneously and competitively, can be systematically modulated by variation of the electronic properties of the ancillary ligand set.

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Reaction of Molecular Oxygen with a Pd^II– Hydride To Produce a Pd^II–Hydroperoxide: Acid Catalysis and Implications for Pd‐Catalyzed Aerobic Oxidation Reactions

Abstract: Palladium-catalyzed reactions are among the most versatile methods for the selective aerobic oxidation of organic molecules.[1] These reactions are generally thought to proceed by a two-stage "oxidase" pathway that consists of Pd II -mediated oxidation of the organic substrate followed by

Cited by 150 publications

References 44 publications

Reactions of Pd and Pt Complexes with Molecular Oxygen

Reactions of Pd and Pt Complexes with Molecular Oxygen

General and Selective Palladium‐Catalyzed Oxidative Esterification of Alcohols

Oxygen Reduction Mechanism of Monometallic Rhodium Hydride Complexes

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Reaction of Molecular Oxygen with a PdII– Hydride To Produce a PdII–Hydroperoxide: Acid Catalysis and Implications for Pd‐Catalyzed Aerobic Oxidation Reactions

Abstract: Palladium-catalyzed reactions are among the most versatile methods for the selective aerobic oxidation of organic molecules.[1] These reactions are generally thought to proceed by a two-stage "oxidase" pathway that consists of Pd II -mediated oxidation of the organic substrate followed by

Cited by 150 publications

References 44 publications

Reactions of Pd and Pt Complexes with Molecular Oxygen

Reactions of Pd and Pt Complexes with Molecular Oxygen

General and Selective Palladium‐Catalyzed Oxidative Esterification of Alcohols

Oxygen Reduction Mechanism of Monometallic Rhodium Hydride Complexes

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Product

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Reaction of Molecular Oxygen with a Pd^II– Hydride To Produce a Pd^II–Hydroperoxide: Acid Catalysis and Implications for Pd‐Catalyzed Aerobic Oxidation Reactions