The σ‐CAM Mechanism: σ Complexes as the Basis of σ‐Bond Metathesis at Late‐Transition‐Metal Centers

Perutz, Robin N.; Sabo-Étienne, Sylviane

doi:10.1002/anie.200603224

Cited by 544 publications

(556 citation statements)

References 145 publications

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“…The hydrogenolysis mechanism of a pincer Ir(III)-CH3 complex was analyzed in detail by Brookhart and co-workers (Scheme 36a). Spectroscopic studies and DFT calculations revealed that reductive elimination of methane proceeds through a σ-metathesis or σ-CAM mechanism, 207 in which the oxidation state of iridium is unaltered over the course of the transformation and where a σ-methane complex 3.18b is an instrumental intermediate. 92b The metal-ligand cooperative hydrogenolysis of a Ni-CH3 bond in 3.19 has recently been disclosed and the role of the boryl ligand in assisting such transformation is supported by computational studies (Scheme 36b).…”

Section: Protonolysis and Hydrogenolysismentioning

confidence: 99%

Methyl Complexes of the Transition Metals

Campos

López‐Serrano

Peloso

et al. 2016

Chemistry A European J

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Organometallic chemistry can be considered as a wide area of knowledge that combines concepts of classic organic chemistry, i.e. based essentially on carbon, with molecular inorganic chemistry, especially with coordination compounds. Transition metal methyl complexes probably represent the simplest and most fundamental way to view how these two major areas of chemistry combine and merge into novel species with intriguing features in terms of reactivity, structure, and bonding. Citing more than 500 bibliographic references, this review aims to offer a concise view of recent advances in the field of transition metal complexes containing M-CH3 fragments. Taking into account the impressive amount of data that are continuously provided by organometallic chemists in this area, this review is mainly focused on results of the last 5 years. After a panoramic overview on M-CH3 compounds of groups 3 to 11 which includes the most recent landmark findings in this area, two further sections are dedicated to methyl-bridged complexes and reactivity.

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Section: Protonolysis and Hydrogenolysismentioning

confidence: 99%

Methyl Complexes of the Transition Metals

Campos

López‐Serrano

Peloso

et al. 2016

Chemistry A European J

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“…E is most commonly H, SiR 3 or BR 2 , but in principal this idea extends to C-H s-complexes. 37 Hall has used the atoms-in-molecules (AIM) approach 38 to characterise different transition states in terms of the varying patterns of bond critical points (BCP) and ring critical points (RCP) (see Fig. 6 Despite this elegant outcome, it seems likely that a continuum of transition state structures will be formed as more computational data become available on SBM processes.…”

Section: Overviewmentioning

confidence: 99%

Mechanisms of C–H bond activation: rich synergy between computation and experiment

et al. 2009

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Image reproduced with permission of Christophe CoperetPapers published in this issue include:A combined picture from theory and experiments on water oxidation, oxygen reduction and proton pumping Per E. M. Siegbahn and Margareta R. A. Blomberg, Dalton Trans., 2009, DOI: 10.1039 Recent computational studies of C-H bond activation at late transition metal systems are discussed and processes where lone pair assistance via heteroatom co-ligands or carboxylates are highlighted as a particularly promising means of cleaving C-H bonds. The term 'ambiphilic metal ligand activation' (AMLA) is introduced to describe such reactions.

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“…2 Thus, coordination of the hydrogen of a silane SiH bond to the coordinatively unsaturated metal center in a complex ML n can lead to the formation of A bearing an η 1 (H)-silane ligand, and then the coordination mode of the silane ligand in A can change to an η 2 -mode to give complex B that has stronger M£Si interaction compared with that in A. Finally, B can be converted either into a hydrido(silyl) complex C via complete oxidative addition or into other types of intermediate via ·-CAM mechanism, 3 etc. Therefore, to understand the detailed reaction mechanism of the SiH activation, it is indispensable to experimentally elucidate how bonding interaction between a metal and an SiH bond (M£H£Si interaction) can gradually change at some different stages of the process.…”

mentioning

confidence: 99%

Silane(silyl) and Bis(silyl)hydrido Manganese Complexes with Different Mn···H···Si Interaction: Observation of Gradual Si–H Bond Activation on the Metal Center

Komuro¹,

Okawara²,

Furuyama³

et al. 2012

Chemistry Letters

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Three manganesecarbonyl complexes having a xanthenebased silane(silyl) or bis(silyl) chelate ligand were synthesized and characterized. The single-crystal X-ray analysis of these complexes demonstrated that an SiH bond is sequentially activated on the metal according to ligand substitution of CO with xanthene-oxygen or η 6 -toluene.The SiH bond activation of hydrosilanes induced by transition-metal complexes is an attractive process for its broad application to the synthesis of organosilicon compounds (e.g., hydrosilylation).1 Generally, it is proposed that this bond activation can be achieved by interaction of the SiH · bond with a coordinatively unsaturated metal center.1 A possible reaction mechanism of the SiH activation suggested by Schubert and co-workers based on their comprehensive study (Scheme 1) involves the generation of silane complexes A and B, both having a 3c2e MHSi bond, as key intermediates.

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The σ‐CAM Mechanism: σ Complexes as the Basis of σ‐Bond Metathesis at Late‐Transition‐Metal Centers

Cited by 544 publications

References 145 publications

Methyl Complexes of the Transition Metals

Methyl Complexes of the Transition Metals

Mechanisms of C–H bond activation: rich synergy between computation and experiment

Silane(silyl) and Bis(silyl)hydrido Manganese Complexes with Different Mn···H···Si Interaction: Observation of Gradual Si–H Bond Activation on the Metal Center

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