Abstract
In search of more active new catalysts, density functional theory was used to predict insertion barriers for ethylene polymerization for a variety of unknown Ti-chelating bridged alkoxide catalysts, [YR‘XR‘Y]TiCH3+, where X, Y = O, S, Se, Te, and R‘ = C6H4, C2H2, C2H4 with and without substituents. The use of ligands having donating and bridging atoms that are capable of donating electron density to the cationic metal center decreases the insertion barriers. For [(C6H4O)X(C6H4O)]TiCH3+, both the olefin coordination energy, X = S(21.4 kcal/mol) > Se(19.2) >Te(16.6), and migratory insertion barrier, X = S(6.4) > Se(5.9) > Te(5.7), decrease with the increasing donating capability of the bridging atom X to the metal center, i.e., via X = S < Se < Te. The oxygen bridge, however, gives the lowest insertion barrier (4.5 kcal/mol) in this group. The role of the phenyl group was explored by replacing it by C2H2 and C2H4 moieties. Having conjugation through the X−CC−Y moiety in these complexes turns out to be very ...
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