A Non Expected Alternative Ni(0) Species in the Ni‐Catalytic Aldehyde and Alcohol Arylation Reactions Facilitated by a 1,5‐Diaza‐3,7‐diphosphacyclooctane Ligand

Heitkämper, Julia; Posada, Sergio; Escayola, Sílvia; Solà, Miquel; Kästner, Johannes; Poater, Albert

doi:10.1002/chem.202300193

Cited by 4 publications

(3 citation statements)

References 103 publications

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“…To understand the different nature of the first two intermediates, we applied EOS analysis (see technical details in the Supporting Information). , The results obtained for different degrees of substitution of the two phenyls attached to the cyclopentadienone are collected in Table S10. The frontier effective fragment orbitals (EFOs) are for the metal (last occupied (LO) with a pair of electrons assigned) versus the cyclopentadienone ligand (first unoccupied (FU)).…”

Section: Resultsmentioning

confidence: 99%

Enhancement of Knölker Iron Catalysts for Imine Hydrogenation by Predictive Catalysis: From Calculations to Selective Experiments

et al. 2023

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The reductive amination reaction of imines catalyzed by Knolker-type iron complexes under hydrogen at high pressure is very interesting in synthetic terms. This type of reaction is an important catalytic challenge, since harsh conditions are necessary and do not occur easily. In a previous work (Organometallics 2022(Organometallics , 41, 1204(Organometallics −1215, we carried out a computational study of the reaction mechanism showing that electron-withdrawing groups (EWGs) attached to the cyclopentadienone of the Knolker-type iron complexes favor the reductive amination of imines. The synthesis of Knolker-type iron complexes with cyclopentadienones having EWGs is not straightforward, since the direct bonding of EWGs on the cyclopentadienone would lead not to the reductive amination but to undesired dimerization. A possible solution consists in the addition of phenyl substituents in the cyclopentadienones of these catalysts and then introduction of EWGs in the phenyl rings. We have performed computational studies using density functional theory (DFT) for the reductive amination of imines to analyze the efficiency of such an approach. We have found that some EWGs in the phenyl groups facilitate the reductive amination of imines. This computational result has been later confirmed experimentally, and therefore, we have computationally designed new catalysts that improve the performances of the previously known Knolker-type iron complexes.

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Section: Resultsmentioning

confidence: 99%

Enhancement of Knölker Iron Catalysts for Imine Hydrogenation by Predictive Catalysis: From Calculations to Selective Experiments

et al. 2023

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“…In addition, although the mechanism of Ni(0) as an active species has been proposed to be feasible, [30] neither the "naked" nor ArBr coordinated Ni(0) species can be afforded here to restart this catalytic cycle; see Figure S8 in the Supporting Information.…”

Section: Resultsmentioning

confidence: 99%

Theoretical Mechanistic Study of C(sp³)−C(sp²) Cross‐Coupling by Photoredox‐Mediated Iridium(III)/Nickel(II)/Quinuclidine Triple Catalysis

Wang

et al. 2023

Chemistry An Asian Journal

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The photoredox-mediated iridium(III)/nickel(II)/3acetoxyquinuclidine triple-synergistic catalysis was comprehensively investigated by taking a C(sp 3 )À C(sp 2 ) bond crosscoupling as a reaction model using density functional theory (DFT) calculations. The synergistic mechanism of the triple catalytic system includes a reductive quenching cycle (Ir III À *Ir III À Ir II À Ir III ), an organocatalytic cycle, and a nickel catalytic cycle (Ni II À Ni I À Ni III À [Ni III ] ⊖ À Ni II ). Electronic process analysis shows that 3-acetoxyquinuclidine acts as a hydrogen atom transfer (HAT) catalyst to regioselectively provide αcarbon centered radical. Due to more favorable oxidative addition of CÀ Br to Ni(I) than HAT to avoid the formation of stable Ni(II) species, the generated α-carbon centered radical prefers to be captured by oxidative addition product Ni(III) to form an unusual [Ni III ] ⊖ C ⊕ species when 3-acetoxyquinuclidine was employed. These theoretical insights not only provide deep electronic process understanding of the photoredoxmediated iridium(III)/nickel(II) synergistic catalysis, but also clarify the electron-withdrawing group effect of quinuclidine, which has a potential guiding role for further development of new cross-coupling reactions.

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“…From the next intermediate I6 , reductive elimination allows to release Ph-Cl into solution (overcoming a barrier of 9.4 kcal/mol through TS4 ). Finally, the resulting intermediate I7 with PhCl and the metal weakly interacting each other releases PhCl to obtain the catalytically active Pd(0) species I8 , , relatively unstable, but still 3.0 kcal/mol lower in energy than the pre-catalyst.…”

Section: Resultsmentioning

confidence: 99%

Suzuki–Miyaura Cross-Coupling of Amides by N–C Cleavage Mediated by Air-Stable, Well-Defined [Pd(NHC)(sulfide)Cl₂] Catalysts: Reaction Development, Scope, and Mechanism

Yang

Liu

et al. 2023

J. Org. Chem.

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The Suzuki–Miyaura cross-coupling of amides by selective N–C acyl bond cleavage represents a powerful tool for constructing biaryl ketones from historically inert amide bonds. These amide bond activation reactions hinge upon efficient oxidative addition of the N–C acyl bond to Pd(0). However, in contrast to the well-researched activation of aryl halides by C(sp2)–X oxidative addition, very few studies on the mechanism of C(acyl)–N bond oxidative addition and catalyst effect have been reported. Herein, we report a study on [Pd(NHC)(sulfide)Cl2] catalysts in amide N–C bond activation. These readily prepared, well-defined, air- and moisture-stable Pd(II)–NHC catalysts feature SMe2 (DMS = dimethylsulfide) or S(CH2CH2)2 (THT = tetrahydrothiophene) as ancillary ligands. The reaction development, kinetic studies, and reaction scope are presented. Extensive DFT studies were conducted to gain insight into the mechanism of C(acyl)–N bond oxidative addition and catalyst activation. We expect that [Pd(NHC)(sulfide)Cl2] precatalysts featuring sulfides as well-defined, readily accessible ancillary ligands will find application in C(acyl)–X bond activation in organic synthesis and catalysis.

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A Non Expected Alternative Ni(0) Species in the Ni‐Catalytic Aldehyde and Alcohol Arylation Reactions Facilitated by a 1,5‐Diaza‐3,7‐diphosphacyclooctane Ligand

Cited by 4 publications

References 103 publications

Enhancement of Knölker Iron Catalysts for Imine Hydrogenation by Predictive Catalysis: From Calculations to Selective Experiments

Enhancement of Knölker Iron Catalysts for Imine Hydrogenation by Predictive Catalysis: From Calculations to Selective Experiments

Theoretical Mechanistic Study of C(sp³)−C(sp²) Cross‐Coupling by Photoredox‐Mediated Iridium(III)/Nickel(II)/Quinuclidine Triple Catalysis

Suzuki–Miyaura Cross-Coupling of Amides by N–C Cleavage Mediated by Air-Stable, Well-Defined [Pd(NHC)(sulfide)Cl₂] Catalysts: Reaction Development, Scope, and Mechanism

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A Non Expected Alternative Ni(0) Species in the Ni‐Catalytic Aldehyde and Alcohol Arylation Reactions Facilitated by a 1,5‐Diaza‐3,7‐diphosphacyclooctane Ligand

Cited by 4 publications

References 103 publications

Enhancement of Knölker Iron Catalysts for Imine Hydrogenation by Predictive Catalysis: From Calculations to Selective Experiments

Enhancement of Knölker Iron Catalysts for Imine Hydrogenation by Predictive Catalysis: From Calculations to Selective Experiments

Theoretical Mechanistic Study of C(sp3)−C(sp2) Cross‐Coupling by Photoredox‐Mediated Iridium(III)/Nickel(II)/Quinuclidine Triple Catalysis

Suzuki–Miyaura Cross-Coupling of Amides by N–C Cleavage Mediated by Air-Stable, Well-Defined [Pd(NHC)(sulfide)Cl2] Catalysts: Reaction Development, Scope, and Mechanism

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Theoretical Mechanistic Study of C(sp³)−C(sp²) Cross‐Coupling by Photoredox‐Mediated Iridium(III)/Nickel(II)/Quinuclidine Triple Catalysis

Suzuki–Miyaura Cross-Coupling of Amides by N–C Cleavage Mediated by Air-Stable, Well-Defined [Pd(NHC)(sulfide)Cl₂] Catalysts: Reaction Development, Scope, and Mechanism