Mechanistic Study of Alkene Hydrosilylation Catalyzed by a β-Dialdiminate Cobalt(I) Complex

Kim, Daniel; Chen, Chi; Mercado, Brandon Q.; Weix, Daniel J.; Holland, Patrick L.

doi:10.1021/acs.organomet.0c00241

Cited by 20 publications

(15 citation statements)

References 74 publications

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“…Catalysts composed of base metals ,− like Ni, − Mn, − Co, − and Fe ,− have been developed for linear-selective alkene hydrosilylation. As a congener of Pt, Ni is especially promising as a base-metal candidate for alkene hydrosilylation.…”

Section: Introductionmentioning

confidence: 99%

(NHC)Ni(0)-Catalyzed Branched-Selective Alkene Hydrosilylation with Secondary and Tertiary Silanes

et al. 2022

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Hydrosilylation is a valuable approach for the construction of organosilanes, which are precursors to silicone materials that are widely incorporated in our everyday lives. The industry currently relies primarily on Karstedt’s catalyst, Pt2(dvtms)3 (dvtms = 1,3-divinyltetramethyldisiloxane), a precious metal catalyst that exhibits linear selectivity, with regioselectivity favoring the branched product remaining an outstanding challenge. The use of more Earth-abundant, base-metal catalysts has been a recent focus for hydrosilylation reactions, and most reports focus on the development of linear-selective catalysts and are commonly limited to primary and/or secondary silanes. We demonstrate that (NHC)Ni(0) (NHC = N-heterocyclic carbene) complexes are active in the branched-selective hydrosilylation of alkenes with secondary or tertiary silanes, including industrially relevant alkoxy- and chlorosilanes. The scope of alkenes and silanes has been expanded beyond what is currently known for Ni-catalyzed hydrosilylation reactions, including both steric and electronic profiles. In-depth mechanistic studies were also carried out, including stoichiometric and catalytic experiments investigating kinetic and thermodynamic reaction parameters. Radical trap experiments suggest against a one-electron pathway. The rate law of the reaction has a normal dependence on the Ni catalyst and silane and has an inverse dependence on the alkene. Deuterium-labeling studies reveal that hydrosilylation proceeds through a Chalk–Harrod-type mechanism, with the alkene reversibly inserting into a Ni–H bond. Hammett analyses show that the rate of reaction is faster with electron-rich alkenes and electron-poor silanes. Additional mechanistic evidence points to the resting state of the catalyst being a (NHC)Ni(alkene)2 complex, and the rate-determining step being migratory insertion and/or reductive elimination.

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Section: Introductionmentioning

confidence: 99%

(NHC)Ni(0)-Catalyzed Branched-Selective Alkene Hydrosilylation with Secondary and Tertiary Silanes

et al. 2022

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“…Although many first‐row metal catalysts have been used for hydrosilylation, mechanistic understanding for many of these systems remains elusive [9f] . Studies of cobalt‐catalysed hydrosilylation reactions using cobalt‐carbonyl [24] and cyclopentadienyl‐cobalt complexes [25] suggested a prevelance of a modified Chalk‐Harrod mechanism of alkene silyl‐metallation followed by carbon‐hydrogen bond forming reductive elimination [26] .…”

Section: Resultsmentioning

confidence: 99%

Cobalt‐Catalysed, Ligand‐Controlled Regiodivergent Alkene Hydrosilylation

Docherty

Dominey²,

Thomas

2021

Asian J Org Chem

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Alkene hydrosilylation is amongst the largest industrial homogenous catalysis processes. Cobalt catalysis offers a sustainable alternative to commonly used platinum catalysts to achieve this transformation. Using two bisiminopyridine cobalt(II) catalysts the regiodivergent hydrosilylation of alkenes has been developed. Variation of pre‐catalyst activator and ligand substituents were investigated to enable the controlled, regiodivergent hydrosilylation of both aryl‐ and alkyl‐substituted alkenes with phenylsilane. In contrast to other regiodivergence strategies, excellent regioselectivity for either isomer was achieved using the same ligand class but differing by a single methyl group (ethyl vs isopropyl).

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“…Based on the experiments and literatures, [33,34] a proposed mechanism was showed in Scheme 2. First, the cobalt catalyst precursor reacts with silane and NaBEt 3 H to provide low-valent [Co] + silyl species I; second, the species I then inserted into alkenes to generate cobalt alkyl intermediate II and forms to intermediates III; in the third step, the species III react with the silane to form the hydrosilylation adduct and the cobalt catalyst enter into the next catalytic cycle.…”

Section: F I G U R Ementioning

confidence: 99%

The synthesis of heterogenous Co‐MOFs and application in the catalytic hydrosilylation of alkenes

Song

et al. 2022

Applied Organom Chemis

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Hydrosilylation employing metal-organic frameworks (MOFs) as the catalyst are promising because of their high catalytic reactivity and sustainability of heterogeneous catalyst. A highly simple and efficient method for the hydrosilylation of olefins catalyzed by an air-stable MOF-cobalt catalysts is developed. This approach is featured by 0.1% of Co-MOFs catalyst with excellent reactivity, recyclability, and good functional group tolerance. The Co-MOFs can catalyze hydrosilylation of styrene or its derivatives with Ph 2 SiH 2 in the presence of NaBHEt 3 . Moreover, the catalysts we developed show excellent stability, and the activity is not significantly reduced after repeating the cycle for five times.

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Mechanistic Study of Alkene Hydrosilylation Catalyzed by a β-Dialdiminate Cobalt(I) Complex

Cited by 20 publications

References 74 publications

(NHC)Ni(0)-Catalyzed Branched-Selective Alkene Hydrosilylation with Secondary and Tertiary Silanes

(NHC)Ni(0)-Catalyzed Branched-Selective Alkene Hydrosilylation with Secondary and Tertiary Silanes

Cobalt‐Catalysed, Ligand‐Controlled Regiodivergent Alkene Hydrosilylation

The synthesis of heterogenous Co‐MOFs and application in the catalytic hydrosilylation of alkenes

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