Single- and Double-Coordination Mechanism in Ethylene Tri- and Tetramerization with Cr/PNP Catalysts

Britovsek, George J. P.; McGuinness, David S.; Wierenga, Tanita S.; Young, Craig T.

doi:10.1021/acscatal.5b00989

Cited by 72 publications

(101 citation statements)

References 64 publications

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“…species [11], hydrogenation of inactive Ti allylic species [12,13] and hydrogenation of unsaturated chain ends that poison active sites. Although progress has been made in understanding the mechanism of PNP/Cr(III)/MAO catalyzed ethylene tetramerization [5,14], most notably the role of a metallacyclic reaction manifold, definitive answers relating to the oxidation state of chromium and specific aspects of ligand control remain elusive. The plausible machenism of how H 2 promotes to reactivate the deactive metal centre is shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

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Hydrogen: efficient promoter for PNP/Cr(III)/MAO catalyzed ethylene tetramerization toward 1-octene

et al. 2016

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The effect of hydrogen addition on the catalytic activity and product selectivity of PNP/Cr(III)/MAO catalytic systems for ethylene tetramerization was investigated. The results showed that the catalytic activity could be increased twice and the polymer production could be reduced efficiently through hydrogen addition. It could be inferred from the analysis and characterization results of the products that there existed at least three sorts of catalytic active centers in the ethylene tetramerization reaction.

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Section: Resultsmentioning

confidence: 99%

“…Since its discovery, a rapid increase in the number of publications and patents have been reported for selective ethylene tetramerization, among which much attention has been paid to the electronic and steric factors of the PNP ligands, reaction mechanism, reaction kinetics and new ligands [2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Hydrogen: efficient promoter for PNP/Cr(III)/MAO catalyzed ethylene tetramerization toward 1-octene

et al. 2016

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“…We did not calculate the minimum energy crossing points (MECPs). In multiple publications the MECP has been demonstrated to be lower in energy than the rate‐determining step . Subsequent oxidative coupling of the two ethene molecules ( TSA1 , ΔΔG ≠ =4.4 kcal mol −1 ) yields chromacyclopentane A4 .…”

Section: Resultsmentioning

confidence: 99%

Investigating the Active Species in a [(R‐SN(H)S‐R)CrCl₃] Ethene Trimerization System: Mononuclear or Dinuclear?

et al. 2019

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Cr-catalyzed ethene trimerization is an industrially important process to produce 1-hexene. Despite its industrial relevance, the changing oxidation state and the structural rearrangements of the metal center during the catalytic cycle remain unclear. In this study, we have investigated the active species in a [(R-SN (H)SÀ R)CrCl 3 ] (R = C 10 H 21 ) catalyzed ethene trimerization system using a combination of spectroscopic techniques (XAS, EPR and UV/VIS) and DFT calculations. Reaction of the octahedral Cr III complex with modified methylaluminoxane (MMAO) in absence of ethene gives rise to the formation of a square-planar Cr II complex. In the presence of ethene (1 bar), no coordination was observed, which we attribute to the endergonic nature of the coordination of the first ethene molecule. Employing an alkyne as a model for ethene coordination leads to the formation of a dinuclear cationic Cr III alkyne complex. DFT calculations show that a structurally related dinuclear cationic Cr III ethene complex could form under catalytic conditions. Comparing a mechanism proceeding via mononuclear cationic Cr II /Cr IV intermediates to that proceeding via dinuclear cationic Cr II /Cr III intermediates demonstrates that only the mechanism involving mononuclear cationic Cr II /Cr IV intermediates can correctly explain the observed product selectivity.[a] B.

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“…for the fabrication of lubricants (C 10 ), biodegradable detergents (C 10 , C 12 , C 14 ), surfactants and lubricant additives (C 12 -C 20 ) and many other useful chemicals. These features explain the continuing interest in both academia and industry for this research area [14][15][16][17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Ligand Control of the Metal Coordination Sphere: Structures, Reactivity and Catalysis

Danopoulos

Braunstein

2016

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Dedicated to the memory of Yves Chauvin, a most remarkable and visionary man and scientist, with gratitude for our scientific and non-scientific conversations and a very fruitful and enjoyable collaboration.Abstract -Two major aspects of coordination/organometallic chemistry are discussed in this article: (i) the use of functional chelating ligands to stabilize metal complexes while allowing easy stereodifferentiation within the coordination sphere and (ii) the choice of suitable ligands to stabilize challenging 'underligated' metal complexes with electronically highly unsaturated metal centres, thus potentially displaying unusual reactivity. In both cases, the relevance to homogeneous catalysis will be discussed.Résumé -Contrôle de la sphère de coordination des métaux par les ligands : structures, réacti-vité et catalyse -Deux aspects majeurs de la chimie de coordination/organométallique sont discutés dans cet article : d'une part, l'utilisation de ligands chélatants fonctionnels pour stabiliser des complexes métalliques en permettant une différenciation stéréoélectronique aisée au sein de la sphère de coordination et, d'autre part, la sélection de ligands adaptés à la stabilisation de complexes métalliques sous-coordinés dont les centres métalliques sont hautement insaturés électroniquement et donc potentiellement le siège d'une réactivité inhabituelle. Dans les deux cas, nous évoquerons la pertinence de ces approches en catalyse homogène.

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Single- and Double-Coordination Mechanism in Ethylene Tri- and Tetramerization with Cr/PNP Catalysts

Cited by 72 publications

References 64 publications

Hydrogen: efficient promoter for PNP/Cr(III)/MAO catalyzed ethylene tetramerization toward 1-octene

Hydrogen: efficient promoter for PNP/Cr(III)/MAO catalyzed ethylene tetramerization toward 1-octene

Investigating the Active Species in a [(R‐SN(H)S‐R)CrCl₃] Ethene Trimerization System: Mononuclear or Dinuclear?

Ligand Control of the Metal Coordination Sphere: Structures, Reactivity and Catalysis

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Single- and Double-Coordination Mechanism in Ethylene Tri- and Tetramerization with Cr/PNP Catalysts

Cited by 72 publications

References 64 publications

Hydrogen: efficient promoter for PNP/Cr(III)/MAO catalyzed ethylene tetramerization toward 1-octene

Hydrogen: efficient promoter for PNP/Cr(III)/MAO catalyzed ethylene tetramerization toward 1-octene

Investigating the Active Species in a [(R‐SN(H)S‐R)CrCl3] Ethene Trimerization System: Mononuclear or Dinuclear?

Ligand Control of the Metal Coordination Sphere: Structures, Reactivity and Catalysis

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Investigating the Active Species in a [(R‐SN(H)S‐R)CrCl₃] Ethene Trimerization System: Mononuclear or Dinuclear?