C–H Activation by Isolable Cationic Bis(phosphine) Cobalt(III) Metallacycles

Whitehurst, William G.; Kim, Junho; Koenig, Stefan G.; Chirik, Paul J.

doi:10.1021/jacs.2c08865

Cited by 14 publications

(8 citation statements)

References 112 publications

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“…The choice of cobalt among the possible metal catalysts for ligand-directed functionalization was determined by its comparative cheapness and availability as well as by its good catalytic activity in C–H functionalizations, both chemical and electrochemical. − Putatively characterized key intermediates, cobaltacycles, or other cobalt structures are still rare and are given in the Introduction (Scheme ) [e.g., in ref ].…”

Section: Resultsmentioning

confidence: 99%

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Mechanism-Driven Development of N-(Quinolin-8-yl)-benzamide Coupling Reactions via C–H or N–H Activation

et al. 2023

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The mechanistic details of the oxidative coupling of compounds with a number of different redox centers are investigated using N-(quinolin-8-yl)-benzamide (L) as a model substrate. The control of the chemical or electrooxidation parameters in the absence or presence of a cobalt catalyst makes it possible to obtain regioselectively different oxidative coupling products (ortho- vs para-C–H/C–H vs C–H/N–H vs N–H/N–H). The results indicate that the operative mechanism depends on the type of oxidized reaction center and the oxidant nature. Oxidation affects the para-C–H bond in quinoline or the N–H fragment or the ortho-C–H bond in the benzene substituent in the molecule. The intermediate Co(II)[L–H]2 complex and C–H-activated CoIII metallacycle with benzamide ligands, which are shown to oxidize at close potentials, have been isolated and characterized by various techniques, including X-ray diffraction and voltammetry. The strength of the oxidizing agent affects the formation of a particular product, though not acting as the determining factor. Two-electron oxidation of Co(II)[L–H]2 yields to C–N coupling, but one-electron oxidation of Co(III) leads to ortho-C–C coupling. All electrochemical reactions are performed under mild conditions at room temperature without adding special reagents (oxidants, halides, phosphines, etc.).

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Section: Resultsmentioning

confidence: 99%

“…Ligand-directed transformations are more selective since they proceed through metallacyclic intermediates which have been isolated and characterized in rare cases or through noncovalent coordination. Although a number of metallacyclic structures have been proved for noble metals, fully characterized cobaltacycles are still rare …”

Section: Introductionmentioning

confidence: 99%

Mechanism-Driven Development of N-(Quinolin-8-yl)-benzamide Coupling Reactions via C–H or N–H Activation

et al. 2023

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“…In addition, the facile syntheses of the new compounds 3 and 4 reveal promising opportunities to further explore the coordination of other small-molecules to the aza-cobalt-cyclobutene bearing complexes. Recently, directed C( sp 2 )–H activation by Co III metallacycle complexes were demonstrated with high selectivity for ortho-alkylation . Inspired by both the activity of Co III metallacycle and recent developments in Co macrocyclic complexes as photocatalysts , and copolymerization catalysts, current efforts are underway to explore the incorporation of photocatalytic activity.…”

Section: Discussionmentioning

confidence: 99%

“…Recently, directed C(sp 2 )−H activation by Co III metallacycle complexes were demonstrated with high selectivity for ortho-alkylation. 33 Inspired by both the activity of Co III metallacycle and recent developments in Co macrocyclic complexes as photocatalysts 34,35 and copolymerization catalysts, 36 current efforts are underway to explore the incorporation of photocatalytic activity.…”

Section: ■ Conclusionmentioning

confidence: 99%

Further Exploration of Aza-Cobalt-Cyclobutenes on Co^III(TIM) Complexes: Reactivity and Spectroelectrochemistry

2023

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The reaction between [CoIII(TIM)Cl2]PF6 (TIM is 2,3,9,10-tetramethyl-1,4,8,11-tetraazacyclotetradeca-1,3,8,10-tetraene) and electron-rich terminal alkynes (HC2Y, Y = 4-N,N-bis(4-methoxyphenyl)aniline (TPA) or Fc) yielded a pair of constitutional isomers: 1-aza-2-cobalt-cyclobutene-containing trans-[Co(TIM′)((HCC)Y)Cl]+ (1a (TPA) and 2a (Fc); TIM′ is the resultant derivative of TIM) and σ-coordinated trans-[Co(TIM)(C2Y)Cl]+ (1b (TPA) and 2b (Fc)). Additionally, the reactivity of the 1-aza-2-cobalt-cyclobutene species was explored based on trans-[Co(TIM′)((HCC)Fc)Cl]PF6 (2a) because of its good synthetic yield. The reaction of 2a with AgOTf in MeCN resulted in trans-[Co(TIM′)((HCC)Fc)(NCMe)](PF6)(OTf) (3), and the reaction with KCN in MeOH yielded trans-[Co(TIM′)((HCC)Fc)CN]PF6 (4). Similarly, trans-[Co(TIM)(C2Ph)(CN)]PF6 (5) was prepared from the reaction between KCN and trans-[Co(TIM)(C2Ph)Cl]PF6. Molecular structures of 1b and 3–5 were established through single crystal X-ray diffraction. Electrochemical studies of 2–4 revealed that these complexes display an irreversible CoIII reduction as well as a reversible one electron ferrocenyl oxidation between 0.11 and 0.18 V (vs Fc+1/0). UV–vis spectroelectrochemical studies revealed a CoIII to Fc+ charge-transfer upon the one electron oxidation of 2a and 2b.

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“…We focused on a metallacycle-mediated C–H activation strategy, where the cleavage of a C–H bond via σ-CAM (σ-complex-assisted metathesis) is triggered by an in situ generated metallacycle formation . Several catalytic directed C–H activation reactions based on this strategy have been reported for Rh and Co catalysts, while Fe catalyst has never been used. Here, we report the iron-catalyzed C(sp 2 )–H alkenylation of benzamides with 1,6-diynes using an iron/photosensitizer hybrid catalyst (Scheme c).…”

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confidence: 99%

Iron/Photosensitizer-Catalyzed Directed C–H Activation Triggered by the Formation of an Iron Metallacycle

2023

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C−H functionalization reactions catalyzed by iron, the most abundant transition metallic element in the Earth's crust, are one of the ideal synthetic methods. However, there are a limited number of strategies for iron-catalyzed directed C−H activation reactions when compared to reactions catalyzed by other first-row transition metals. Here, we report the iron/photosensitizer-catalyzed C−H alkenylation of amide derivatives via a σ-CAM (σ-complex-assisted metathesis) promoted by the in situ generation of an iron metallacycle. Mechanistic experiments suggest that the C−H bond cleavage would proceed via the σ-CAM from a metallacycle generated in situ rather than via the oxidative addition to a low-valent iron species.

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C–H Activation by Isolable Cationic Bis(phosphine) Cobalt(III) Metallacycles

Cited by 14 publications

References 112 publications

Mechanism-Driven Development of N-(Quinolin-8-yl)-benzamide Coupling Reactions via C–H or N–H Activation

Mechanism-Driven Development of N-(Quinolin-8-yl)-benzamide Coupling Reactions via C–H or N–H Activation

Further Exploration of Aza-Cobalt-Cyclobutenes on Co^III(TIM) Complexes: Reactivity and Spectroelectrochemistry

Iron/Photosensitizer-Catalyzed Directed C–H Activation Triggered by the Formation of an Iron Metallacycle

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C–H Activation by Isolable Cationic Bis(phosphine) Cobalt(III) Metallacycles

Cited by 14 publications

References 112 publications

Mechanism-Driven Development of N-(Quinolin-8-yl)-benzamide Coupling Reactions via C–H or N–H Activation

Mechanism-Driven Development of N-(Quinolin-8-yl)-benzamide Coupling Reactions via C–H or N–H Activation

Further Exploration of Aza-Cobalt-Cyclobutenes on CoIII(TIM) Complexes: Reactivity and Spectroelectrochemistry

Iron/Photosensitizer-Catalyzed Directed C–H Activation Triggered by the Formation of an Iron Metallacycle

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Product

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Further Exploration of Aza-Cobalt-Cyclobutenes on Co^III(TIM) Complexes: Reactivity and Spectroelectrochemistry