Density functional calculations on agostic ethyl-Ti (IV) complexes

First principles, density functional theory embodied in the DMol program has been applied to agostic ethyl-Ti-complexes, including the dmpe complex, [Ti(-CH 2CH 3)C1 3(dmpe)], where dmpe=(Me 2PCH 2) 2 and its model complex, [Ti(−CH 2CH 3)Cl 3(PH 3) 2]. The ethyl moiety of the complexes can adopt two...

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Bibliographic Details
Published in:Catalysis today 1995-04, Vol.23 (4), p.403-408
Main Authors: Munakata, Hiroaki, Ebisawa, Yukiko, Takashima, Yuka, Wrinn, Michael C., Scheiner, Andrew C., Newsam, John M.
Format: Article
Language:English
Subjects:
Applied sciences
Chemistry
Coordination compounds
Exact sciences and technology
Inorganic chemistry and origins of life
Organic polymers
Physicochemistry of polymers
Polymerization
Preparation, kinetics, thermodynamics, mechanism and catalysts
Preparations and properties
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Summary:First principles, density functional theory embodied in the DMol program has been applied to agostic ethyl-Ti-complexes, including the dmpe complex, [Ti(-CH 2CH 3)C1 3(dmpe)], where dmpe=(Me 2PCH 2) 2 and its model complex, [Ti(−CH 2CH 3)Cl 3(PH 3) 2]. The ethyl moiety of the complexes can adopt two limiting conformations, staggered and eclipsed. In the model complex, [Ti(−CH 2CH 3)C1 3(PH 3) 2], both conformers are found to form agostic structures upon geometry optimization subject to Cs symmetry constraint, with the agostic eclipsed structure being the lower in energy. Full geometry optimization of the dmpe complex, [Ti(−CH 2CH 3)C1 3(dmpe)], yields an agostic structure with geometrical features similar to those measured by single crystal X-ray analysis. It is shown that the HOMO orbital contributes substantially to the agostic bonding.
ISSN:0920-5861
1873-4308
DOI:10.1016/0920-5861(94)00156-V