The Influence of Structure on Reactivity in Alkene Metathesis

Nelson, David J.; Percy, Jonathan M.

doi:10.1016/b978-0-12-800256-8.00002-3

Cited by 5 publications

(6 citation statements)

References 203 publications

(309 reference statements)

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“…26c It has been observed in several cases that the gemdisubstitution of a diene backbone favors cyclization reactions. 29 However, the observed reversal of the E/Z stereoselectivity in the current study seems counterintuitive. The E/Z geometry of a metathesis product is controlled at the metallacyclobutane intermediate, where the alkyl or aryl substituents R are remote from the four-membered ring (Scheme 4).…”

Section: Synthesiscontrasting

confidence: 80%

E/ZSwitchable Ring-Closing Metathesis in 1,1′-Bis(but-3-enyl)ferrocenes: Synthesis and Characterization of Axially Chiralansa[6]-Ferrocenes

et al. 2022

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A series of ansa[6]-ferrocenes were obtained through the ruthenium-catalyzed ring-closing olefin metathesis in 1,1′-bis(but-3enyl)ferrocenes. The stereoselectivity of this reaction depended on the structure of substrates, that is, mixtures of (E) and (Z) isomers were obtained for alkyl-substituted 3a−3d while (Z)-isomers only for arylsubstituted 3e and 3f. The ansa[6]-ferrocenes are axially chiral in the solid state according to single-crystal X-ray analysis. In the case of methyl-substituted derivative 4a, spontaneous resolution of the racemate was observed during crystallization. The solution properties of (E) and (Z) isomers are remarkably different; the latter displays inequivalence of the two formally identical parts of the molecule at low temperature.

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Section: Synthesiscontrasting

confidence: 80%

E/ZSwitchable Ring-Closing Metathesis in 1,1′-Bis(but-3-enyl)ferrocenes: Synthesis and Characterization of Axially Chiralansa[6]-Ferrocenes

et al. 2022

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“…In contrast, an associative interchange mechanism could also rationalize the observed KIE for dx -DME , where steric clash between the NHC and the incoming monomer would be alleviated by the shorter C–D bonds. Ru benzylidene precatalysts like 3 have been proposed to initiate via an associative interchange mechanism . In particular, Plenio and co-workers showed that initiation of 3 and related derivatives is a combination of both an associative interchange and dissociative exchange mechanism, with smaller substrates favoring the associative interchange pathway .…”

Section: Results and Discussionmentioning

confidence: 99%

“…Ru benzylidene precatalysts like 3 have been proposed to initiate via an associative interchange mechanism. 32 In particular, Plenio and co-workers showed that initiation of 3 and related derivatives is a combination of both an associative interchange and dissociative exchange mechanism, with smaller substrates favoring the associative interchange pathway. 33 Lloyd-Jones and co-workers have also shown that the reaction of third generation Ru catalysts with vinyl ethers proceeds via a combination of both mechanisms, with an associative interchange mechanism dominating at higher substrate concentration, 34 supporting calculations by Grela.…”

Section: Journal Of the American Chemical Societymentioning

confidence: 99%

Examining the Effects of Monomer and Catalyst Structure on the Mechanism of Ruthenium-Catalyzed Ring-Opening Metathesis Polymerization

2019

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The mechanism of Ru-catalyzed ring-opening metathesis polymerization (ROMP) is studied in detail using a pair of third generation ruthenium catalysts with varying sterics of the N-heterocyclic carbene (NHC) ligand. Experimental evidence for polymer chelation to the Ru center is presented in support of a monomer-dependent mechanism for polymerization of norbornene monomers using these fast-initiating catalysts. A series of kinetic experiments, including rate measurements for ROMP, rate measurements for initiation, monomer-dependent kinetic isotope effects, and activation parameters were useful for distinguishing chelating and nonchelating monomers and determining the effect of chelation on the polymerization mechanism. The formation of a chelated metallacycle is enforced by both the steric bulk of the NHC and by the geometry of the monomer, leading to a ground-state stabilization that slows the rate of polymerization and also alters the reactivity of the propagating Ru center toward different monomers in copolymerizations. The results presented here add to the body of mechanistic work for olefin metathesis and may inform the continued design of catalysts for ROMP to access new polymer architectures and materials.

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“…Importantly, however, calculations performed on nontruncated GII and GIIm show the same trends in magnetic shielding as a function of the systematic increase in the internuclear Ru–P distances (see SI, Table S1 and Figure S8). It should be noted that dispersion corrections, while critical for treating the energy of ligand loss and binding in these complexes, , are less relevant to assessment of CS tensor values …”

Section: Resultsmentioning

confidence: 99%

Sterically Driven Olefin Metathesis: The Impact of Alkylidene Substitution on Catalyst Activity

Lummiss

Perras

McDonald³

et al. 2016

Organometallics

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The dramatic reactivity difference between the Grubbs metathesis catalysts and their resting-state methylidene derivatives was probed in an integrated crystallographic, solid-state NMR and localized molecular orbital analysis study. A principal focus was the second-generation Grubbs system RuCl2(H2IMes)(PCy3)(CHR) (GII, R = Ph; GIIm, R = H); supporting studies were carried out with the first-generation species RuCl2(PCy3)2(CHR) (GI, GIm). The compiled rate constants for PCy3 dissociation demonstrate the limited lability of the methylidene complexes (e.g., ca. 275-fold lower for GIIm than GII and nearly 2000 times lower for the IMes analogue GIIm′). This is important because it impedes catalyst re-entry from the resting state into the active cycle. The 31P chemical shift (CS) tensors for the PCy3 ligand exhibited the expected changes (i.e., those characteristic of an increased Ru–P orbital interaction) in GIIm relative to GII, as did GIm vs GI. Greater insight was offered by the 13C CS tensors. Whereas calculations on truncated models predict significant differences in 13C CS tensor values for GII compared with GIIm, the experimental values are equivalent, implying a compensating effect that weakens the RuC interaction in the benzylidene complex. Published X-ray crystallographic parameters for GII and GI reveal that one chloride ligand is displaced below the basal plane by steric interactions with the benzylidene phenyl group, an effect absent in GIIm and GIm. During PCy3 loss from the [Ru]CHPh systems, established processes of alkylidene rotation transform Ph–Cl repulsion into Ph–PCy3 repulsion. Displacing the PCy3 ligand below the plane does not relieve this conflict, instead incurring steric interactions with the H2IMes ligand. Enhanced PCy3 lability in the benzylidene complexes, relative to their methylidene analogues, is hence proposed to originate in the steric pressure exerted by the Ph substituent.

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The Influence of Structure on Reactivity in Alkene Metathesis

Cited by 5 publications

References 203 publications

E/ZSwitchable Ring-Closing Metathesis in 1,1′-Bis(but-3-enyl)ferrocenes: Synthesis and Characterization of Axially Chiralansa[6]-Ferrocenes

E/ZSwitchable Ring-Closing Metathesis in 1,1′-Bis(but-3-enyl)ferrocenes: Synthesis and Characterization of Axially Chiralansa[6]-Ferrocenes

Examining the Effects of Monomer and Catalyst Structure on the Mechanism of Ruthenium-Catalyzed Ring-Opening Metathesis Polymerization

Sterically Driven Olefin Metathesis: The Impact of Alkylidene Substitution on Catalyst Activity

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