Oligomerization cyclooligomerization

The catalytic transformation of olefins by transition metal complexes has received a great deal of attention during the past two decades. These catalytic reactions are important, especially industrially, because they represent some of the most economical ways to synthesize olefinic monomers or polymers. The more common types of these transformation reactions are (a) dimerization or polymerization of a-olefins (b) dimerization, oligomerization, cyclooligomerization, or polymerization of con-... 

Review W. Reim, A. Behr, M. Roper, Alkene and alkyne oligomerization, cyclooligomerization and telomerization reactions, in Comprehensive Organometallic Chemistry, (Eds. G. Wilkinson, F. G. A. Stone, E. W. Abel), I rgamon, Oxford, 1984. 

The cyclooligomerization of ethylene oxide to yield dioxane as well as compounds we now call crowns predates Pedersen s discovery by more than a decade ". The full utility of these cyclic oligomers was not recognized, however, and the patent reporting these early efforts remains an interesting historical footnote. The promise of utilizing cyclo-oligomerization commercially is so important, however, that attention is called to the method and the existence of the patent. 

Another limitation of the traditional Cu-mediated cyclooligomerization reaction is generation of differentially substituted PDMs. In the above case, the substitution pattern in the starting o-diethynylbenzene must be maintained on each and every benzene moiety in the oligomeric mixture of PDMs that is produced. Thus, it is impossible to prepare less symmetric systems like 100 via this route. With the intramolecular synthetic approach, however, it should be possi-... 

The catalytic cyclo-oligomerization of 1,3-butadiene mediated by transition-metal complexes is one of the key reactions in homogeneous catalysis.1 Several transition metal complexes and Ziegler-Natta catalyst systems have been established that actively catalyze the stereoselective cyclooligomerization of 1,3-dienes.2 Nickel complexes, in particular, have been demonstrated to be the most versatile catalysts.3... 

Dimerization, Oligomerization, and Cyclooligomerization Catalyzed by Supported Metal Complexes... 

In the case of reactions such as valence isomerization, metathesis reactions of alkenes and alkynes, oligomerization or cyclooligomerization of olefins, metallacycloalkanes are of special importance. Their catalytic efficiency depends on the ease of the M—C bond cleavage, which is the result of reductive elimination of the organic substrate or of /J-hydrogen transfer. Also a- or / -C—C bond rupture has been reported. Heterocycles with an aliphatic carbon skeleton and a donor atom adjacent to the metal are suitable model compounds for the study of individual catalytic steps and structural properties. In connection with the activation of C—H bonds, cyclometa-lation has become a very general reaction and was reviewed in 1977. ... 

Many transition metals catalyze oligomerization reactions between dienes and olefins or alkynes. Possible reaction products are legion. But it is almost exclusively with zerovalent nickel that cyclic products are formed. Addition of olefins or alkynes to catalysts mentioned in the previous section suppresses the cyclooligomerization and instead gives cyclo-co-oligomerization products. 

As mentioned above, many transition metals catalyze the cyclooligomerization of 1,3-dienes. The nickel-catalyzed cyclooligomerization of BD, however, is probably one of the best-understood reactions in the field of homogeneous catalysis. In the 40 years since its discovery a mass of evidence has been collected, indicating that these oligomerizations are the result of a multistep addition-elimination mechanism at a nickel atom template, which constantly flips between two oxidation states. The following strategies played an important role isolation of key intermediates, simulation of the catalytic cycle in a stoichiometric manner, product analysis, and study of model compounds. Detailed analysis of the intellectual development of the mechanism is not included here as this can be followed from excellent reviews [6]. 

The catalytic behavior of Pd in 1,3-diolefin oligomerizations is quite different from that of Ni. Cyclooligomerization, as in the case of Ni catalysis, is normally not observed. Pd-catalyzed reactions of 1,3-diolefins are characterized by linear oligomerizations with H-migrations yielding, in the absence of nucleophiles, linear dimers or trimers . Another typical feature of Pd catalysis is the facile formation of dimeric telomers with incorporation of various nucleophiles (alcohols, carboxylic acids, amines) ". A variety of Pd(0) complexes and also of Pd(II) complexes, which are more easily accessible and may be reduced in situ to Pd(0), have been examined . Some selected examples are given in Table 1. 

In the presence of suitable cocatalysts such as alcohols, phenols, or secondary amines, 1,3-diolefins are oligomerized to linear dimers or trimers by the same nickel-ligand systems, which are effective for cyclooligomerization (see 14.5.2.5.1). Reactions may be accompanied by telomerization. Typical examples are given in Table 1. 

The oligomerization and cyclooligomerization of dienes is a synthetically useful and commercially significant reaction catalyzed by transition-metal complexes from different triads. In nearly all examples, -allyl complexes are intermediates, formed by either coupling of dienes about a metal template or by insertion of the diene into a metal-H bond. Allyl complexes are isolated from stoichiometric and catalytic diene oligomeriza-... 

Co-Oligomerization of 1,3-Butadiene and Ethylene vs Cyclooligomerization of 1,3-Butadiene Promoted by Zerovalent Bare Nickel Complexes ... 

This chapter is organized as follows. In the following section the tentative catalytic cycle proposed by Wilke and co-workers is outlined, followed, in the next section, by a short description of the computational approach employed and the catalyst model chosen. The structural and energetic aspects of all critical elementary steps of the complete catalytic cycle are presented after that. Then we propose a theoretically verified, refined catalytic reaction cycle, and follow that with the elucidation of the product distribution between linear and cyclic Cjo-olefins. Finally, the catalytic reaction courses of the [Ni°]-catalyzed co-oligomerization of 1,3-butadiene and ethylene and of the cyclooligomerization of 1,3-butadiene are compared. 

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