Density Functional Study of Ethylene Dimerization by (Acetylacetonato)nickel Hydride

Fan, Liangyou; Krzywicki, A.; Somogyvari, A.; Ziegler, Tom

doi:10.1021/ic00101a021

Cited by 33 publications

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“…Ziegler et al calculated the ethylene dimerization path for [Ni(acac)H] using DFT. − Insertion of ethylene into the Ni–H or the Ni-ethyl bonds are facile and exothermic steps. While chain termination by β-H elimination is an endothermic step, calculations for alternative paths suggest a preferred β-H transfer to ethylene.…”

Section: Active Sites and Mechanism(s)mentioning

confidence: 64%

Nickel Catalyzed Olefin Oligomerization and Dimerization

et al. 2020

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Brought to life more than half a century ago and successfully applied for high-value petrochemical intermediates production, nickel-catalyzed olefin oligomerization is still a very dynamic topic, with many fundamental questions to address and industrial challenges to overcome. The unique and versatile reactivity of nickel enables the oligomerization of ethylene, propylene and butenes into a wide range of oligomers that are highly sought-after in numerous fields to be controlled. Interestingly, both homogeneous and heterogeneous nickel catalysts have been scrutinized and employed to do this. This rare specificity encouraged us to interlink them in this review so as to open up opportunities for further catalyst development and innovation. An in-depth understanding of the reaction mechanisms in play is essential to being able to fine-tune the selectivity and achieve efficiency in the rational design of novel catalytic systems. This review thus provides a complete overview of the subject, compiling the main fundamental/industrial milestones and remaining challenges facing homogeneous/heterogeneous approaches as well as emerging catalytic concepts, with a focus on the last 10 years.

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Section: Active Sites and Mechanism(s)mentioning

confidence: 64%

Nickel Catalyzed Olefin Oligomerization and Dimerization

et al. 2020

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“…As far as the mechanism of the formation of 6 and propene is concerned, we suggest that complex 5 reacts with ethene by insertion into the Ni−CH 3 bond (rate-determining step) to form the intermediate [(d t bpe)Ni(C 3 H 7 )(OSO 2 CF 3 )] ( G ), which is structurally related to 6 and 6a . Intermediate G , as a result of β-H activation, eliminates propene to give the Ni II −hydride intermediate [(d t bpe)Ni(H)(OSO 2 CF 3 )] ( H ), which rapidly inserts ethene into the Ni−H bond to yield 6 (Scheme ) …”

Section: Resultsmentioning

confidence: 99%

Synthesis, Structure, and Reactivity of (^tBu₂PC₂H₄P^tBu₂)Ni(CH₃)₂ and {(^tBu₂PC₂H₄P^tBu₂)Ni}₂(μ-H)₂

et al. 1998

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Oxidative addition of CH3I to (dtbpe)Ni(C2H4) (dtbpe = tBu2PC2H4PtBu2) affords (dtbpe)Ni(I)CH3 (1). The reaction of (dtbpe)NiCl2 or 1 with the stoichiometric quantity of (tmeda)Mg(CH3)2 yields (dtbpe)Ni(CH3)2 (2). (dtbpe)Ni(I)CD3 (1-d 3) and (dtbpe)Ni(CD3)2 (2-d 6) have been prepared analogously. Thermolysis of 2 in benzene affords {(dtbpe)Ni}2(μ-η2:η2-C6H6) (4). The reaction of either 2 or 4 with hydrogen (H2, HD, D2) gives {(dtbpe)Ni}2(μ-H)2 (3) and the isotopomers {(dtbpe)Ni}2(μ-H)(μ-D) (3-d) and {(dtbpe)Ni}2(μ-D)2 (3-d 2). According to the NMR spectra, the structure of 3 is dynamic in solution. The crystal structures of 2 and 3 have been determined by X-ray crystallography. Solution thermolysis of 2 or reduction of (dtbpe)NiCl2 with Mg* in the presence of alkanes probably involves σ-complex-type intermediates [(dtbpe)Ni(η2-R‘H)] (R‘ = e.g. C2H5, A). While the nonisolated [(dtbpe)Ni0] σ-complexes A are exceedingly reactive intermediates, isolated 3 and 4 represent easy to handle starting complexes for [(dtbpe)Ni0] reactions. Partial protolysis of 2 with CF3SO3H affords (dtbpe)Ni(CH3)(OSO2CF3) (5). Complex 5 reacts slowly with 2 equiv of ethene to give equimolar amounts of [(dtbpe)Ni(C2H5)]+(OSO2CF3 -) (6) and propene. The reaction is thought to be initiated by an insertion of ethene into the Ni−CH3 bond of 5 to form the intermediate [(dtbpe)Ni(C3H7)(OSO2CF3)] (G), followed by elimination of propene to give the hydride intermediate [(dtbpe)Ni(H)(OSO2CF3)] (H), which on insertion of ethene into the Ni−H bond affords 6.

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“…273−275 For the cationic nickel system bearing a 2-(2-pyridyl)benzimidazole ligand, the hydride intermediate has been identified by ESI-MS. 275 It is generally believed that a 3-coordinate nickel hydride is needed to initiate the oligomerization process (Scheme 101). 240,241 The vacant coordination site is first occupied by ethylene and then left open following ethylene insertion. β-Hydride elimination from the propagating alkyl chain gives α-olefins and regenerates the nickel hydride.…”

Section: Oligomerization or Polymerization Of Alkenes/alkynesmentioning

confidence: 99%

“…Reaction of alkenes with nickel hydrides, specifically, has major implications for ethylene oligomerization. DFT calculations on the acac ligand system suggest that a 3-coordinate nickel hydride (acac)NiH is the key intermediate, which adopts a planar geometry and allows ethane to coordinate cis to the hydride. , Consistent with this mechanistic proposal, the related nickel hydride [κ P , κ O -Ph 2 PCH 2 C(CF 3 ) 2 O]Ni(H)(PCy 3 ) is inactive for catalytic ethylene oligomerization, but the mixture of Ni(COD) 2 and Ph 2 PCH 2 C(CF 3 ) 2 OH is catalytically active. The inertness of the isolated nickel hydride is likely due to PCy 3 blocking the vacant coordination for ethylene.…”

Section: Stoichiometric Reactionsmentioning

confidence: 99%

Nickel Hydride Complexes

2016

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Nickel hydride complexes, defined herein as any molecules bearing a nickel hydrogen bond, are crucial intermediates in numerous nickel-catalyzed reactions. Some of them are also synthetic models of nickel-containing enzymes such as [NiFe]-hydrogenase. The overall objective of this review is to provide a comprehensive overview of this specific type of hydride complexes, which has been studied extensively in recent years. This review begins with the significance and a very brief history of nickel hydride complexes, followed by various methods and spectroscopic or crystallographic tools used to synthesize and characterize these complexes. Also discussed are stoichiometric reactions involving nickel hydride complexes and how some of these reactions are developed into catalytic processes.

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Density Functional Study of Ethylene Dimerization by (Acetylacetonato)nickel Hydride

Cited by 33 publications

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Nickel Catalyzed Olefin Oligomerization and Dimerization

Nickel Catalyzed Olefin Oligomerization and Dimerization

Synthesis, Structure, and Reactivity of (^tBu₂PC₂H₄P^tBu₂)Ni(CH₃)₂ and {(^tBu₂PC₂H₄P^tBu₂)Ni}₂(μ-H)₂

Nickel Hydride Complexes

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Density Functional Study of Ethylene Dimerization by (Acetylacetonato)nickel Hydride

Cited by 33 publications

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Nickel Catalyzed Olefin Oligomerization and Dimerization

Nickel Catalyzed Olefin Oligomerization and Dimerization

Synthesis, Structure, and Reactivity of (tBu2PC2H4PtBu2)Ni(CH3)2 and {(tBu2PC2H4PtBu2)Ni}2(μ-H)2

Nickel Hydride Complexes

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Synthesis, Structure, and Reactivity of (^tBu₂PC₂H₄P^tBu₂)Ni(CH₃)₂ and {(^tBu₂PC₂H₄P^tBu₂)Ni}₂(μ-H)₂