Selective Aromatic C–H Hydroxylation Enabled by η<sup>6</sup>-Coordination to Iridium(III)

D’Amato, Erica M.; Neumann, Constanze N.; Ritter, Tobias

doi:10.1021/acs.organomet.5b00731

Cited by 15 publications

(12 citation statements)

References 55 publications

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“…During the past several decades, many metals have been studied in catalytic activation and functionalization of carbon-hydrogen bonds. The reader is directed to selected recent examples with gold [123], cobalt [124][125][126] chromium [127], copper [128][129][130][131] iron [132][133][134][135], iridium [136], manganese [137][138][139], molybdenum [140], nickel [141], osmium [142][143][144][145][146][147][148], palladium [149][150][151], rhenium [152], rhodium [153,154], ruthenium [155,156], and vanadium [157,158].…”

Section: Metal Ions Most Active In Oxidation Catalysismentioning

confidence: 99%

New Trends in Oxidative Functionalization of Carbon–Hydrogen Bonds: A Review

Shul’pin

2016

Catalysts

170

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This review describes new reactions catalyzed by recently discovered types of metal complexes and catalytic systems (catalyst + co-catalyst). Works of recent years (mainly 2010-2016) devoted to the oxygenations of saturated, aromatic hydrocarbons and other carbon-hydrogen compounds are surveyed. Both soluble metal complexes and solid metal compounds catalyze such transformations. Molecular oxygen, hydrogen peroxide, alkyl peroxides, and peroxy acids were used in these reactions as oxidants.

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Section: Metal Ions Most Active In Oxidation Catalysismentioning

confidence: 99%

New Trends in Oxidative Functionalization of Carbon–Hydrogen Bonds: A Review

Shul’pin

2016

Catalysts

170

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“…Along with numerous examples of expansive metal-based (e.g. Au [83], Ir [84], Os [85,86], Pd Scheme 1. General scheme of synthesis of hexacoppergermsesquioxanes 1e6 containing additional N-ligands (1,10-phenanthroline or 2,2 0 -bipyridine).…”

Section: Introductionmentioning

confidence: 99%

Hexacoppergermsesquioxanes as complexes with N-ligands: Synthesis, structure and catalytic properties

Kulakova

Korlyukov

Zubavichus

et al. 2019

Journal of Organometallic Chemistry

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A simple and versatile strategy of synthesis of cage metallagermaniumsesquioxanes is demonstrated for isolation of Cu 6-based phenylgermsesquioxanes 1e6. Structure of newly synthesized coppergermsesquioxanes was established by single-crystal X-ray diffraction analysis. General principle of these cages' topology implies the presence of two linear Cu 3 fragments, coordinated by three pairs of ligands. These are: (i) cyclic germsesquioxanes [PhGeO 1,5 ] 5 , products 1e6, (ii) 1,10-phenanthrolines, (1, 3e5) or 2,2'bipyridines, (2, 6), (or and (iii) OX species (X ¼ H, 1e2, CH 3 , 3, H and C 2 H 5 O, 4, HCO, 5, CH 3 CO, 6). Appearance of non-expected species (formiate for 5, acetate for 6), resulted from corresponding alcohols used as reaction media, points at easyness of oxidation processes in the conditions of such selfassembling reactions. Catalytic tests showed high activity of complexes 1 and 2 as precatalysts in homogeneous oxidations of alkanes (cyclohexane, methylcyclohexane, n-heptane, cis-1,2dimethylcyclohexane with hydrogen peroxide in acetonitrile solution. Hydroxyl radicals take part in the reaction. The same complexes catalyze oxidation of alcohols (cyclohexanol, 2-heptanol, 1phenylethanol) to corresponding ketones with tert-butyl hydroperoxide in almost 100% yield. With the addition of various alkyl ammonium salts, complex 2 could also furnish corresponding amides in high yield.

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“…With a few exceptions that generally require a large excess of aromatic compounds to drive arene‐exchange in catalysis, [11] umpolung aromatic substitutions have relied on the use of stoichiometric η 6 ‐arene complexes as substrates, which are preformed and require additional steps to liberate free arenes [9] . One obstacle to realizing catalytic reactions is that some of the conditions used for liberation of the arene from the metal center, such as oxidation, [9f] photolysis, [9p] and ligand exchange, [9j,l] are incompatible with the substitutions. Specifically, η 6 ‐phenol complexes readily undergo deprotonation under the basic conditions typically required for nucleophilic addition; the resulting η 5 ‐phenoxo isomers do not undergo arene dissociation [9j,l, 11e, 12] .…”

Section: Introductionmentioning

confidence: 99%

“…One obstacle to realizing catalytic reactions is that some of the conditions used for liberation of the arene from the metal center, such as oxidation, [9f] photolysis, [9p] and ligand exchange, [9j,l] are incompatible with the substitutions. Specifically, η 6 ‐phenol complexes readily undergo deprotonation under the basic conditions typically required for nucleophilic addition; the resulting η 5 ‐phenoxo isomers do not undergo arene dissociation [9j,l, 11e, 12] . In comparison, phenyl alkyl ethers are unable to tautomerize into phenoxo isomers, and their use would thus overcome the obstacle to realization of catalytic S N Ar reactions [13] .…”

Section: Introductionmentioning

confidence: 99%

Catalytic S_NAr Hydroxylation and Alkoxylation of Aryl Fluorides

Kang

Lin

et al. 2021

Angewandte Chemie

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Nucleophilic aromatic substitution (S N Ar) is a powerful strategy for incorporating a heteroatom into an aromatic ring by displacement of a leaving group with a nucleophile, but this method is limited to electron-deficient arenes. We have now established a reliable method for accessing phenols and phenyl alkyl ethers via catalytic S N Ar reactions. The method is applicable to a broad array of electron-rich and neutral aryl fluorides, which are inert under classical S N Ar conditions. Although the mechanism of S N Ar reactions involving metal arene complexes is hypothesized to involve a stepwise pathway (addition followed by elimination), experimental data that support this hypothesis is still under exploration. Mechanistic studies and DFT calculations suggest either a stepwise or stepwise-like energy profile. Notably, we isolated a rhodium h 5cyclohexadienyl complex intermediate with an sp 3 -hybridized carbon bearing both a nucleophile and a leaving group. Scheme 1. Approaches to phenols from aryl halides.

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Selective Aromatic C–H Hydroxylation Enabled by η⁶-Coordination to Iridium(III)

Cited by 15 publications

References 55 publications

New Trends in Oxidative Functionalization of Carbon–Hydrogen Bonds: A Review

New Trends in Oxidative Functionalization of Carbon–Hydrogen Bonds: A Review

Hexacoppergermsesquioxanes as complexes with N-ligands: Synthesis, structure and catalytic properties

Catalytic S_NAr Hydroxylation and Alkoxylation of Aryl Fluorides

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Selective Aromatic C–H Hydroxylation Enabled by η6-Coordination to Iridium(III)

Cited by 15 publications

References 55 publications

New Trends in Oxidative Functionalization of Carbon–Hydrogen Bonds: A Review

New Trends in Oxidative Functionalization of Carbon–Hydrogen Bonds: A Review

Hexacoppergermsesquioxanes as complexes with N-ligands: Synthesis, structure and catalytic properties

Catalytic SNAr Hydroxylation and Alkoxylation of Aryl Fluorides

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Product

Resources

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Selective Aromatic C–H Hydroxylation Enabled by η⁶-Coordination to Iridium(III)

Catalytic S_NAr Hydroxylation and Alkoxylation of Aryl Fluorides