Oxidative addition and C–H activation chemistry with a PNP pincer-ligated cobalt complex

Semproni, Scott P.; Atienza, Crisita Carmen Hojilla; Chirik, Paul J.

doi:10.1039/c4sc00255e

Cited by 77 publications

(97 citation statements)

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“…Pathways involving reductive elimination of either H 2 or HBPin seem the most plausible as Co(I)−Co(III) redox cycles are amply precedented in [(PNP)Co] chemistry. 8a,22,23 As presented in Scheme 2, the “hydride pathway” generates ( iPr PNP)CoH following reductive elimination of HBPin, whereas the alternative “boryl pathway” involves H 2 loss to access ( iPr PNP)CoBPin , analogous to the intermediate responsible for C−H activation during the borylation of 2,6-lutidine with B 2 Pin 2 . 8a Because of the trans disposition of the hydride ligands in trans -( iPr PNP)Co-(H) 2 BPin , isomerization to the cis isomer either by phosphine dissociation 24 or HBPin reductive coupling is required to achieve an appropriate geometry for H 2 loss.…”

Section: Resultsmentioning

confidence: 99%

“…Heating the THF- d 8 solution of the reaction mixture to 80 °C for 32 h produced 19% yield of the borylated product and a new cobalt compound identified as 4-BPin-( iPr PNP)Co(H)(PH i Pr 2 ) . This product, arising from P−C bond cleavage of the pincer, 22 was independently synthesized from addition of HP i Pr 2 to 4-BPin-( iPr PNP)CoCH 3 8a under an atmosphere of hydrogen gas (see complete experimental details on page S9) and crystallographically characterized (Figure 6). Performing the C−H borylation of 2,6-lutidine with HBPin in 0.55 M THF solution using 10 mol % of 4-BPin-( iPr PNP)Co(H)(PH i Pr 2 ) as the precatalyst resulted in no conversion to the borylated product, establishing that the formation of 4-BPin-( iPr PNP)Co(H)-(PH i Pr 2 ) by P−C bond cleavage is a catalyst deactivation pathway (see S10).…”

Section: Resultsmentioning

confidence: 99%

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Mechanistic Studies of Cobalt-Catalyzed C(sp²)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Obligacion

Chirik

2017

ACS Catal.

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Studies into the mechanism of cobalt-catalyzed C(sp2)−H borylation of five-membered heteroarenes with pinacolborane (HBPin) as the boron source established the catalyst resting state as the trans-cobalt(III) dihydride boryl, (iPrPNP)Co(H)2(BPin) (iPrPNP = 2,6-(iPr2PCH2)2(C5H3N)), at both low and high substrate conversions. The overall first-order rate law and observation of a normal deuterium kinetic isotope effect on the borylation of benzofuran versus benzofuran-2-d1 support H2 reductive elimination from the cobalt(III) dihydride boryl as the turnover-limiting step. These findings stand in contrast to that established previously for the borylation of 2,6-lutidine with the same cobalt precatalyst, where borylation of the 4-position of the pincer occurred faster than the substrate turnover and arene C−H activation by a cobalt(I) boryl is turnover-limiting. Evaluation of the catalytic activity of different cobalt precursors in the C−H borylation of benzofuran with HBPin established that the ligand design principles for C− H borylation depend on the identities of both the arene and the boron reagent used: electron-donating groups improve catalytic activity of the borylation of pyridines and arenes with B2Pin2, whereas electron-withdrawing groups improve catalytic activity of the borylation of five-membered heteroarenes with HBPin. Catalyst deactivation by P−C bond cleavage from a cobalt(I) hydride was observed in the C−H borylation of arene substrates with C−H bonds that are less acidic than those of five-membered heteroarenes using HBPin and explains the requirement of B2Pin2 to achieve synthetically useful yields with these arene substrates.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Mechanistic Studies of Cobalt-Catalyzed C(sp²)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Obligacion

Chirik

2017

ACS Catal.

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“…With these considerations in mind, the flexible diisopropyl-substituted bis(phosphino)pyridine pincer ligand ( iPr PNP) was selected for this study due to its known ability to support both tetrahedral (X = Cl) and planar (X = alkyl, aryl) cobalt(I) complexes. 50−54 Furthermore, the ( iPr PNP)cobalt platform promotes two-electron oxidative addition 53 and has been applied to catalytic C–H borylation. 50,52 …”

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“…Thus, the catalytically relevant route to the ( iPr PNP)CoOR species was explored using the known cobalt(I) chloride ( iPr PNP)CoCl. 53 Addition of 1 equiv of NaOPh in THF- d 8 solution resulted in formation of ( iPr PNP)CoOPh as the major product observed by 1 H NMR spectroscopy (Scheme 6). Addition of 2-benzofuranylBPin to the resulting THF- d 8 solution produced a mixture containing ( iPr PNP)CoCl as the only cobalt species observable by 1 H NMR spectroscopy.…”

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Insight into Transmetalation Enables Cobalt-Catalyzed Suzuki–Miyaura Cross Coupling

2016

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Among the fundamental transformations that comprise a catalytic cycle for cross coupling, transmetalation from the nucleophile to the metal catalyst is perhaps the least understood. Optimizing this elementary step has enabled the first example of a cobalt-catalyzed Suzuki–Miyaura cross coupling between aryl triflate electrophiles and heteroaryl boron nucleophiles. Key to this discovery was the preparation and characterization of a new class of tetrahedral, high-spin bis(phosphino)pyridine cobalt(I) alkoxide and aryloxide complexes, (iPrPNP)CoOR, and optimizing their reactivity with 2-benzofuranylBPin (Pin = pinacolate). Cobalt compounds with small alkoxide substituents such as R = methyl and ethyl underwent swift transmetalation at 23 °C but also proved kinetically unstable toward β–H elimination. Secondary alkoxides such as R = iPr or CH(Ph)Me balanced stability and reactivity. Isolation and structural characterization of the product following transmetalation, (iPrPNP)Co(2-benzofuranyl), established a planar, diamagnetic cobalt(I) complex, demonstrating the high- and low-spin states of cobalt(I) rapidly interconvert during this reaction. The insights from the studies in this elementary step guided selection of appropriate reaction conditions to enable the first examples of cobalt-catalyzed C–C bond formation between neutral boron nucleophiles and aryl triflate electrophiles, and a model for the successful transmetalation reactivity is proposed.

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“…During the last three decades, many successful applications of catalytic C-H functionalization reactions directed toward the construction of C-C or C-N bonds have been reported in synthetic communities. Many transition metals, such as manganese [6], iron [7], cobalt [8], nickel [9], ruthenium [10], rhodium [11,12], palladium [9,[13][14][15][16][17], iridium [18], and platinum [19] have been found to catalyze C-H functionalization reactions.…”

Section: Introductionmentioning

confidence: 99%

Theoretical studies of palladium-catalyzed cycloaddition of alkynyl aryl ethers and alkynes

Meng

Wang

2014

J Mol Model

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Density functional theory (DFT) was used to investigate palladium(0)-catalyzed cycloaddition of alkynyl aryl ethers and alkynes to generate 2-methylidene-2H-chromenes. Calculations indicated that the cycloaddition had five possible reaction pathways: I, II, III, IV, and V. In the palladium(0)-alkynyl aryl ether complex IM1, the oxidative addition of the Caryl-H bond occurred prior to the dissociation of a ligand PMe3. The dissociation of a ligand PMe3 from the five-coordinated complex IM2 was much easier to achieve than the hydrogen transfer reaction and the substitution reaction of alkynes. In the palladium(0)-hydride complex IM4, the hydrogen migration of H1 from palladium to carbon C1 was much easier to achieve than migration to carbon C2. In the four-coordinated aryl-palladium-alkyne complexes IM6a and IM6b, the alkyne insertion reaction into the Pd-Caryl bond occurred prior to that into the Pd-Calkenyl bond. The reaction channel IM1 → TS1 → IM2 → IM4 → TS3a → IM5a → IM6a → TS4a1 → IM7a1 → TS5a1 → IM8a was the most favorable among the catalytic reaction pathways of the cycloaddition of alkynyl aryl ethers and 2-butynes catalyzed by the palladium(0)/PMe3 complex. Moreover, hydrogen migration was the rate-determining step for this channel. The dominant product was 2-methylidene-2H-chromenes P1, which is in agreement with experimental studies.

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Oxidative addition and C–H activation chemistry with a PNP pincer-ligated cobalt complex

Abstract: The bis(phosphino)pyridine (PNP) cobalt(i) methyl complex, (iPrPNP)CoCH3is a rich platform for the oxidative addition of non-polar reagents such as H2, the C–H bonds of arenes and terminal alkynes.

Cited by 77 publications

References 68 publications

Mechanistic Studies of Cobalt-Catalyzed C(sp²)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Mechanistic Studies of Cobalt-Catalyzed C(sp²)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Insight into Transmetalation Enables Cobalt-Catalyzed Suzuki–Miyaura Cross Coupling

Theoretical studies of palladium-catalyzed cycloaddition of alkynyl aryl ethers and alkynes

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Oxidative addition and C–H activation chemistry with a PNP pincer-ligated cobalt complex

Abstract: The bis(phosphino)pyridine (PNP) cobalt(i) methyl complex, (iPrPNP)CoCH3is a rich platform for the oxidative addition of non-polar reagents such as H2, the C–H bonds of arenes and terminal alkynes.

Cited by 77 publications

References 68 publications

Mechanistic Studies of Cobalt-Catalyzed C(sp2)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Mechanistic Studies of Cobalt-Catalyzed C(sp2)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Insight into Transmetalation Enables Cobalt-Catalyzed Suzuki–Miyaura Cross Coupling

Theoretical studies of palladium-catalyzed cycloaddition of alkynyl aryl ethers and alkynes

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Mechanistic Studies of Cobalt-Catalyzed C(sp²)–H Borylation of Five-Membered Heteroarenes with Pinacolborane

Mechanistic Studies of Cobalt-Catalyzed C(sp²)–H Borylation of Five-Membered Heteroarenes with Pinacolborane