Cycloolefin/conjugated diene

Coordination polymerisation via re complexes comprises polymerisation and copolymerisation processes with transition metal-based catalysts of unsaturated hydrocarbon monomers such as olefins [11-19], vinylaromatic monomers such as styrene [13, 20, 21], conjugated dienes [22-29], cycloolefins [30-39] and alkynes [39-45]. The coordination polymerisation of olefins concerns mostly ethylene, propylene and higher a-olefins [46], although polymerisation of cumulated diolefins (allenes) [47, 48], isomerisation 2, co-polymerisation of a-olefins [49], isomerisation 1,2-polymerisation of /i-olcfins [50, 51] and cyclopolymerisation of non-conjugated a, eo-diolefins [52, 53] are also included among coordination polymerisations involving re complex formation. 

The stereoregularity of polymers relates not only to the configuration of four substituents attached to saturated carbon atoms in the polymer chains but also to the geometric isomerism, resulting from the presence of unsaturated carbon atoms in the polymer chains. Such isomerism appears in chains of polymers formed in the 1,4 polymerisation of conjugated dienes [scheme (19)] and the polymerisation of acetylenes [scheme (20)] as well as the ring-opening polymerisation of cycloolefins [scheme (16)] ... 

Ever since their original discoveries, Ziegler Natta catalysts and Phillips catalysts have been used for both the homopolymerisation and the copolymerisation of olefins. Moreover, Ziegler-Natta catalysts also allowed the copolymerisation of olefins with vinylaromatic monomers, conjugated dienes and cycloolefins. Other coordination catalysts such as group 8 metal compounds, especially cationic Pd(II) complexes, enabled the alternating copolymerisation of olefins and carbon monoxide [2,29,30,37,43,46,241,448 450],... 

By contrast, copolymerizations of norbomene with higher a-olefins or styrenes and conjugated dienes, or of poly cycloolefins, still give low activity, low comonomer incorporation, and low molar masses. Thus, synthesis of new organome-talUc complexes with various metal centers and with ancillary ligands with appropriate stmcture will play an important role for their controlled copolymerization, which can lead to COC with desired physical, mechanical, and optical properties. 

Abstract Metallocene complexes that serve as stereoselective olefin polymerization catalysts are described. The polymerization of propylene, styrene, methyl methacrylate, 1,3-dienes, non-conjugated dienes and cycloolefins is discussed. The stereochemistry of monomer insertion is governed by the chiral steric environment of catalysts derived from a ligand structure (catalytic-site control) or a chiral center in the polymer chain (chain-end control). The mechanism of formation of isotactic and syndiotactic polymers in each monomer and catalyst is explained. Non-metallocene catalysts for stereospecific polymerization are also mentioned. 

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