Transition metal-halogen bonds, insertion

Compounds containing Sn—Cu, Sn—Ag and Sn—Au bonds are prepared by inserting SnClj into the transition metal-halogen bond ... 

We have shown, however, that a significant number of monohalogen-oalkyl transition metal compounds have now been prepared, many of them in the last decade. A variety of routes have been used to synthesize these compounds, but the most common ones are (1) the reaction of an alkoxyalkyl compound with anhydrous HX (X = Cl, Br, or I), (2) the reaction of a nucleophilic transition metal compound with a dihaloalkane, and (3) the insertion of a methylene group into a metal-halogen bond. The most common route to the co-halogenoalkyl complexes is by reaction of an anionic metal species with the a,co-dihaloalkane. These monohalo-... 

Three approaches to zinc enolates are commonly adopted the process associated to the classical Reformatsky reaction is based on the insertion of Zn(0) into the carbon—halogen bond of an a-haloester. Two additional routes involve (i) transmetallation of a lithium enolate with a Zn(II) salt (Section V.A) and (ii) the transition-metal-catalysed conjugate addition of diethylzinc to Michael acceptors (Section V.B). 

A long-standing success in transition metal catalysis is the carbonylation reaction [66], in particular the synthesis of acetic acid [67]. Formally this is the insertion of CO into another bond, in particular into a carbon-halogen bond. After the oxidative addition to the transition metal (the breaking of the carbon-halogen bond), a reaction with a CO ligand takes place. This reaction is often called an insertion. Mechanistic studies have, however, shown that the actual reaction... 

In certain instances (Ir, Pt, Au), the carbon-transition-metal-mercury complexes are actually isolable. They also decompose in the manner indicated. When organomercury halides are employed in such reactions, similar oxidation-reduction processes occur, but evidence suggests that the transition metal inserts primarily into the mercury-halogen bond followed by loss of mercury " ... 

This mechanism is quite general for this substitution reaction in transition metal hydride-carbonyl complexes [52]. It is also known for intramolecular oxidative addition of a C-H bond [53], heterobimetallic elimination of methane [54], insertion of olefins [55], silylenes [56], and CO [57] into M-H bonds, extmsion of CO from metal-formyl complexes [11] and coenzyme B12- dependent rearrangements [58]. Likewise, the reduction of alkyl halides by metal hydrides often proceeds according to the ATC mechanism with both H-atom and halogen-atom transfer in the propagation steps [4, 53]. 

The study of the reactivity of transition metal hydride compounds towards unsaturated organic molecules, mainly olefines and alkynes, has been traditionally centered in monohydrides. In general, the reactions lead to the insertion products, alkyl or alkenyl, which have a limited chemistry. Furthermore, the generation of subsequent carbon-carbon or carbon-heteroatom bonds requires the presence of other active ligands, such as halogen or carbon monoxide, in the coordination sphere of the metallic center of the alkyl or alkenyl intermediates. 

As with other transition metal-catalyzed reactions (Ziegler-Natta polymerization of alkenes, olefin metathesis), the mechanism of the Heck reaction is complicated. In brief, the species that reacts with the aryl halide is I Pd, where L is a ligand such as tiiphenylphosphine. By a process known as oxidative addition, palladium inserts into the carbon-halogen bond of the aryl halide. 

With Zn Lewis acids, only single a-insertion of alkynes (—> 42) is observed, while with AlMes double alkenylation (— 43) dominates. It is proposed that oxidative Ni(0) insertion to the 2-CH bond, hydronickelation of the triple bond, alkenyl transfer to C-2 of the pyridine, and reductive Ni-elimination are the decisive steps in the catalytic cycle, (d) The pyridyl residue may serve as a directing group in C-H insertion reactions of phenyl substituents at pyridine mediated by transition metals like Cu and Pd. For instance, 2-phenylpyridine can be regioselectively halogenated, acetoxylated, and cyanided (- products 44, 45, and 47) in the presence of Cu(OAc)2 [92] or amidated — 46) in the presence of Pd(OAc)2 [93] ... 

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