Transition metal complexes intermolecular activation processes

Equation (1) depicts an early example of an intermolecular addition of an alkane C-H bond to a low valent transition metal complex [12], Mechanistic investigations provided strong evidence that these reactions occur via concerted oxidative addition wherein the metal activates the C-H bond directly by formation of the dative bond, followed by formation of an alkylmetal hydride as the product (Boxl). Considering the overall low reactivity of alkanes, transition metals were able to make the C-H bonds more reactive or activate them via a new process. Many in the modern organometallic community equated C-H bond activation with the concerted oxidative addition mechanism [10b,c]. 

Axially chiral biaryls are an important class of molecules primarily because of their biological activity, as well as their use as chiral ligands. Although enantioselective cyclotrimerization of 1,6-diynes with alkynes or nitriles catalyzed by transition metals has been developed, it was difficult to realize the intermolecular cross-cyclotrimerization process with three alkynes. However, a cationic Rh-complex with (5)-H8-BINAP was found to catalyze effectively the regioselective and enantioselective intermolecular cross-cyclotrimerization of two alkynes 392 and 394 to give chiral biaryls 395 with 89-96% ee in good yields (Scheme 2-35). ... 

Bergman et al. [12] reported one of the first studies of C—H bond activation with a transition metal system capable of intermolecular oxidative addition. The reaction involved the photolysis of [Ir(ri-Cp )(PMe3)(H)J in different hydrocarbon solvents. Figure 25.5 shows that the reaction likely proceeds via loss to form a very reactive IF 16 electron metal intermediate. The C—H activation proceeds via a 3-centered transition state leads to an Ir hydrido-alkyl complex in a high yield at room temperature. The process is well described as an oxidative addition of the alkane. 

Now, one must wonder if there is any limit to the ability of metals to bond in a stable way to other o bonds, including those in non-reactive molecules like alkanes. In fact, evidence for an intermediate methane complex has been found at low temperature in the reductive elimination of methane from a cationic rhenium methyl hydride [34]. The ab initio theoretical study of the intermolecular process of oxidative addition of a methane C - H bond has led to the location of transition states where the bond is partially broken [35]. The same results have been fond for intramolecular oxidative additions which are related to agostic interactions. In fact, agostic interaction itself is a kind of non-oxidative coordination [15,36]. For unsaturated substrates like ethylene, the activation of a C - H bond seems to follow an intermolecular path, without any previous coordination of the double bond. A feasible explanation consists here of the fact that metal orbitals suitable for ethylene coordination are the same as those which are responsible for oxidative addition, thus making the processes competitive [37]. 

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