The Autocatalytic Isomerization of Allylbenzene by Nickel(0) Tetrakis(triethylphosphite)

Bartlett, Stuart A.; Badiola, Katrina A.; Arandiyan, Hamidreza; Masters, Anthony F.; Maschmeyer, Thomas

doi:10.1002/ejic.201800462

Cited by 6 publications

(5 citation statements)

References 21 publications

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“…Maschmeyer forscht auf den Gebieten Katalyse, nachhaltige Prozesse, erneuerbare Rohstoffe, ionische Flüssigkeiten, mikro‐ und mesoporöse nanostrukturierte Materialien sowie reversible Energiespeichereinheiten. Er beschrieb in der Angewandten Chemie die Charakterisierung polymerer Kohlenstoffnitrid‐Photokatalysatoren, und sein Beitrag über [Ni{(POEt) 3 } 4 ] in der katalytischen Isomerisierung von Allylbenzol wurde zum Titelbild des European Journal of Inorganic Chemistry gewählt . Maschmeyer ist Mitglied der internationalen Beiräte von ChemCatChem , ChemPlusChem und der Zeitschrift für allgemeine und anorganische Chemie .…”

Section: Ausgezeichnet …unclassified

Neues Mitglied der Deutschen Akademie der Naturforscher Leopoldina: Michael Sattler / Australian Museum Eureka Prizes: T. Maschmeyer und E. J. New / Alfred C. Egerton Gold Medal: K. Kohse‐Höinghaus

2018

Angewandte Chemie

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Section: Ausgezeichnet …unclassified

Neues Mitglied der Deutschen Akademie der Naturforscher Leopoldina: Michael Sattler / Australian Museum Eureka Prizes: T. Maschmeyer und E. J. New / Alfred C. Egerton Gold Medal: K. Kohse‐Höinghaus

2018

Angewandte Chemie

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“…Maschmeyer's research interests include catalysis, sustainable processes, renewable feedstocks, ionic liquids, micro‐ and mesoporous nanostructured materials, and reversible energy‐storage devices. He has reported in Angewandte Chemie on the characterization of polymeric carbon nitride photocatalysts, and his report on the use of [Ni{(POEt) 3 } 4 ] in the catalytic isomerization of allylbenzene was featured on the cover of the European Journal of Inorganic Chemistry . Maschmeyer is on the International Advisory Boards of ChemCatChem , ChemPlusChem , and the Zeitschrift für allgemeine und anorganische Chemie .…”

Section: Featured …mentioning

confidence: 99%

Elected to the Deutsche Akademie der Naturforscher Leopoldina: M. Sattler / Australian Museum Eureka Prizes: T. Maschmeyer and E. J. New / Alfred C. Egerton Gold Medal: K. Kohse‐Höinghaus

2018

Angew Chem Int Ed

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“…Transition metal-catalyzed isomerization reactions typically proceed via one of three possible mechanisms: (i) radical pathway, ,,, (ii) π-allyl pathway, or (iii) insertion/elimination via a metal hydride (Figure a). Nickel catalysts are particularly attractive not only because Ni is an Earth-abundant, first-row transition metal but also because they are mechanistically versatile (i.e., able to proceed through 1-electron and 2-electron pathways). ,− Ni has been proposed to isomerize alkenes through insertion/elimination, − radical, and π-allyl-type ,,, mechanisms. The insertion/elimination pathway using a Ni–H catalyst is particularly attractive because it is the proposed mechanism for many chain walking applications. ,,,− Elucidation of the active species structure and the effect of ancillary ligands has been specifically identified as the major challenge in Ni-catalyzed remote functionalization reactions .…”

Section: Introductionmentioning

confidence: 99%

“…Previous work has accessed Ni–H species in situ (Figure b) for alkene isomerization and remote functionalization by oxidative addition of strong acids [e.g., H 2 SO 4 , ,,, HCl, HBF 4 , and HN(SO 2 CF 3 ) 2 or polar O–H bonds , ], oxidative addition of alkyl halides followed by β-hydride elimination, or reduction of Ni(II) with additives that can limit functional group tolerance (e.g., Grignard reagents, , NaBH 4 , − LiAlH 4 , LiBHEt 3 , ,, SnCl 2 , and MAO). In remote functionalization applications, the use of Ni–X (X = halide) complexes in conjunction with a silane as the H-source by the Zhu lab ,,, and others ,, has achieved efficient and selective reactivity for the remote functionalization of alkenes.…”

Section: Introductionmentioning

confidence: 99%

Modular Ni(0)/Silane Catalytic System for the Isomerization of Alkenes

et al. 2022

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Alkenes are used ubiquitously as starting materials and synthetic targets in all areas of chemistry. Controlling their geometry and position along a chain is vital to their reactivity and properties yet remains challenging. Alkene isomerization is an atom-economical process to synthesize targeted alkenes, and selectivity can be controlled using transition metal catalysts. The development of mild, selective isomerization reactivity has enabled efficient tandem catalytic systems for the remote functionalization of alkenes, a process in which a starting alkene is isomerized to a new position prior to the functionalization step. The key challenges in developing isomerization catalysts for remote functionalization applications are (i) a lack of modularity in the catalyst structure and (ii) the requirement of nonmodular and/or harsh additives during catalyst activation. We address both challenges with a modular (NHC)Ni(0)/silane catalytic system (NHC, N-heterocyclic carbene), demonstrating the use of triaryl silanes and readily accessible (NHC)Ni(0) complexes to form the proposed active (NHC)(silyl)Ni−H species in situ. We show that modification of the steric and electronic nature of the catalyst via modification of the ancillary ligand and silane partner, respectively, is easily achieved, creating a uniquely versatile catalytic system that is effective for the formation of internal alkenes with high yield and selectivity for the E-alkene. The use of silanes as mild activators enables isomerization of substrates with a variety of functional groups, including acid-labile groups. The broad substrate scope, enabled by catalyst design, makes this catalytic system a strong candidate for use in tandem catalytic applications. Preliminary mechanistic studies support a Ni−H insertion/elimination pathway.

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The Autocatalytic Isomerization of Allylbenzene by Nickel(0) Tetrakis(triethylphosphite)

Cited by 6 publications

References 21 publications

Neues Mitglied der Deutschen Akademie der Naturforscher Leopoldina: Michael Sattler / Australian Museum Eureka Prizes: T. Maschmeyer und E. J. New / Alfred C. Egerton Gold Medal: K. Kohse‐Höinghaus

Neues Mitglied der Deutschen Akademie der Naturforscher Leopoldina: Michael Sattler / Australian Museum Eureka Prizes: T. Maschmeyer und E. J. New / Alfred C. Egerton Gold Medal: K. Kohse‐Höinghaus

Elected to the Deutsche Akademie der Naturforscher Leopoldina: M. Sattler / Australian Museum Eureka Prizes: T. Maschmeyer and E. J. New / Alfred C. Egerton Gold Medal: K. Kohse‐Höinghaus

Modular Ni(0)/Silane Catalytic System for the Isomerization of Alkenes

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