Alkylidene complexes Electrophilic, reactions

The reactivity of a remarkable electronically unsaturated tantalum methyli-dene complex, [p-MeCgH4C(NSiMe3)2]2Ta( = CH2)CH3, has been investigated. Electrophilic addition and olefination reactions of the Ta = CH2 functionality were reported. The alkylidene complex participates in group-transfer reactions not observed in sterically similar but electronically saturated analogs. Reactions with substrates containing unsaturated C-X (X = C, N, O) bonds yield [Ta] = X compounds and vinylated organic products. Scheme 117 shows the reaction with pyridine N-oxide, which leads to formation of a tantalum 0x0 complex. ... 

The synthesis and X-ray structural determination of a stable Ir111 hydride/alkylidene complex, (165), has been reported, in which the tridentate N3 ligand is TpMe2. 9 The complex undergoes reversible hydride migration onto the electrophilic carbene atom, as shown in reaction Scheme 20. 

The characteristic reactivity of neutral dg alkylidene complexes of Ru, Os, and Ir is with electrophilic reagents. The osmium methylene 47 reacts with the widest range of electrophiles, the most significant reactions being summarized in Scheme 2. 

Reactivity characteristic of alkylidene complexes of tantalum is that the a-carbon is susceptible to electrophilic attack, in contrast to the electron-deficient a-carbon of Fischer-type carbene complexes of group 6 transition metals [62]. Based on this unique property of the alkylidene metal-carbon double bond, a range of new types of reactions has been developed. The discovery of the alkylidene complexes of tantalum was a key to understanding the mechanism of olefin metathesis, and they continue to play important roles in C—H bond activation, alkyne polymerization, and ring-opening metathesis polymerization. 

This reactivity series and the stereochemistry of the cyclopropane adducts. Contrasting with that observed in the case of pentacarbonyldiphenyl carbene, indicate that the reaction first involves an electrophilic attack of the alkylidene complex on the alkene without prior formation of an alkene-metal complex. A transition state (see Fig. 1) involves the formation of a bond from the alkylidene carbon atom to the less substituted end of the alkene and interaction of the positively polarized, more substituted end of the alkene with the carbon atom of the phenyl group. 

Actually, terminal metal carbene and alkylidene complexes are ubiquitous throughout the transition elements. The nomenclatural distinction between "carbene" and "alkylidene" represents a fundamental difference in reactivity. Metal carbene complexes usually behave as electrophiles, with typical reactions including cycloadditions to un-saturabed bonds (e.g. cyclopropanation of olefins). On the other hand, metal alkylidene complexes are nucleophilic, undergoing Wittig-type alkylations and olefin metathesis. 

Pettit-type electrophilic alkylidene complexes reaction of an acid with a methoxy ligand, protonation of a vinyl complex, reaction of a diazo or another source of carbene on a complex that has a vacant coordination site or a labile ligand. 

A decade after Fischer s synthesis of [(CO)5W=C(CH3)(OCH3)] the first example of another class of transition metal carbene complexes was introduced by Schrock, which subsequently have been named after him. His synthesis of [((CH3)3CCH2)3Ta=CHC(CH3)3] [11] was described above and unlike the Fischer-type carbenes it did not have a stabilizing substituent at the carbene ligand, which leads to a completely different behaviour of these complexes compared to the Fischer-type complexes. While the reactions of Fischer-type carbenes can be described as electrophilic, Schrock-type carbene complexes (or transition metal alkylidenes) show nucleophilicity. Also the oxidation state of the metal is generally different, as Schrock-type carbene complexes usually consist of a transition metal in a high oxidation state. 

Complex 169 is very susceptible to electrophilic attack, as shown in Scheme 32. The protonation of 169 with PyHCl gave back 166. In this reaction, the assistance of one of the oxygens as the primary site of the protonation cannot be excluded. The alkylation with MeOTf, unlike in the case of 161 (see Scheme 29),22 occurs at the alkylidene carbon as well, forming the 2,3-dimethyl-2-butene-W derivative 167, which was obtained also by the direct synthesis given in Scheme 31. 

The effect of metal basicity on the mode of reactivity of the metal-carbon bond in carbene complexes toward electrophilic and nucleophilic reagents was emphasized in Section II above. Reactivity studies of alkylidene ligands in d8 and d6 Ru, Os, and Ir complexes reinforce the notion that electrophilic additions to electron-rich compounds and nucleophilic additions to electron-deficient compounds are the expected patterns. Notable exceptions include addition of CO and CNR to the osmium methylene complex 47. These latter reactions can be interpreted in terms of non-innocent participation of the nitrosyl ligand. 

The stoichiometric interaction of an enyne and [RuCl(PCy3)(pcymene)]B(Ar )4 XVIIIa containing a bulky non-coordinating anion B(ArF)4 showed by NMR at —30 ° C the formation of the alkenyl alkylidene ruthenium complex and acrolein. This formation could be understood by the initial formation of a vinylidene intermediate and transfer of a hydride from the oxygen a-carbon atom to the electrophilic vinylidene carbon, as a retroene reaction step (Scheme 8.13) [54]. 

Carbenes, generated by several methods, are reactive intermediates and used for further reactions without isolation. Carbenes can also be stabilized by coordination to some transition metals and can be isolated as carbene complexes which have formal metal-to-carbon double bonds. They are classified, based on the reactivity of the carbene, as electrophilic heteroatom-stabilized carbenes (Fischer type), and nucleophilic methylene or alkylidene carbenes (Schrock type). 

A key chain growth step in Fischer-Tropsch reactions may be the insertion of a methylidene ligand into a metal-alkyl bond. Evidence has been presented that such an insertion occurs in a transient tungsten-methylidene methyl complex [equation (15)] and that this reaction becomes highly favorable when the alkylidene center is electrophilic. 

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