Ex Uno Plures ("Out of One, Many"): New Paradigms for Expanding the Range of Polyolefins through Reversible Group Transfers

One catalyst, many materials: The chemistry of polyolefins has been thoroughly explored, and it sometimes seems as if any given polymer structure can be obtained by derivatization of the coordination catalyst. But this one catalyst, one material concept is self‐limiting. Recently introduced bimolecu...

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Bibliographic Details
Published in:Angewandte Chemie International Edition 2009-03, Vol.48 (14), p.2464-2472
Main Author: Sita, Lawrence R.
Format: Article
Language:English
Subjects:
coordination polymerization
homogeneous catalysis
living polymerization
polyolefins
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Summary:One catalyst, many materials: The chemistry of polyolefins has been thoroughly explored, and it sometimes seems as if any given polymer structure can be obtained by derivatization of the coordination catalyst. But this one catalyst, one material concept is self‐limiting. Recently introduced bimolecular group‐transfer reactions make a wide range of polyolefin materials accessible from a single catalyst by simple variation of reaction parameters. The “mature” status presently enjoyed by polyolefins prepared with homogeneous (soluble) single‐site catalysts through the transition‐metal‐catalyzed coordination polymerization of ethene and 1‐alkenes brings with it a common impression that it is now routinely possible to obtain, with a high degree of confidence, any desired stereochemical microstructure or copolymer composition through iterative optimization employing a set of mutationally related synthetic derivatives generated from an initial molecular design. The dominant reliance on this “one catalyst, one material” strategic approach to discovery is intrinsically self‐limiting, however, owing to the limited pool of molecular structures that can be reasonably synthesized and drawn upon. Recently, non‐chain‐terminating, reversible group‐transfer processes have been purposefully introduced to olefin coordination polymerization. These processes, which are highly competitive with propagation, can be controlled externally and now provide the basis for new “one catalyst, many materials” paradigms that have the potential to greatly expand the reach of polyolefin materials for the 21st century. One catalyst, many materials: The chemistry of polyolefins has been thoroughly explored, and it sometimes seems as if any given polymer structure can be obtained by derivatization of the coordination catalyst. But this one catalyst, one material concept is self‐limiting. Recently introduced bimolecular group‐transfer reactions make a wide range of polyolefin materials accessible from a single catalyst by simple variation of reaction parameters.
ISSN:1433-7851
1521-3773
DOI:10.1002/anie.200802661