Macromolecular Engineering via Carbocationic Polymerization: Branched Structures, Block Copolymers and Nanostructures

Macromolecular Engineering via Carbocationic Polymerization: Branched Structures, Block Copolymers and Nanostructures

This article features macromolecular engineering via carbocationic polymerization, the focus of research of the recently established Macromolecular Engineering Research Centre (MERC) at the University of Western Ontario. The fundamental philosophy of MERC is interdisciplinary research with a strong...

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Published in:Macromolecular materials and engineering Vol. 286; no. 10; pp. 565 - 582
Main Authors: Puskas, Judit E., Antony, Prince, Kwon, Yongmoon, Paulo, Christophe, Kovar, Milan, Norton, Peter R., Kaszas, Gabor, Altstädt, Volker
Format: Journal Article
Language:English
Published: Weinheim WILEY-VCH Verlag GmbH 01-10-2001
WILEY‐VCH Verlag GmbH
Wiley-VCH
Subjects:
Applied sciences
Exact sciences and technology
Organic polymers
Physicochemistry of polymers
Polymerization
Preparation, kinetics, thermodynamics, mechanism and catalysts
Branched polymer
Preparation
Living polymer
Diblock copolymer
Reaction mechanism
Nanostructure
Star polymer
Cationic polymerization
Review
Kinetics
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Summary:This article features macromolecular engineering via carbocationic polymerization, the focus of research of the recently established Macromolecular Engineering Research Centre (MERC) at the University of Western Ontario. The fundamental philosophy of MERC is interdisciplinary research with a strong industrial orientation, while emphasizing the quest for fundamental understanding of polymerization processes and polymer structure‐property relationships. First, a brief overview of living polymerizations in general, and living carbocationic polymerizations in particular will be given. This latter technique is of interest because some monomers (e. g., isobutylene) can be polymerized by cationic techniques only, to yield polymers with unique properties (e. g., polyisobutylene with superior chemical and oxidative stability, low permeability and high damping). This will be followed by an overview of our research strategy and a summary of our latest results. These include the development of a fiber‐optic mid‐FTIR method for the real‐time monitoring of low temperature polymerization processes, the discovery that selected epoxides initiate effectively the living carbocationic polymerization of isobutylene, fundamental studies into the mechanism and kinetics of living carbocationic polymerization, and the design and synthesis of various polymer architectures (e. g., branched homo‐ and block copolymers) with improved properties and nanostructured phase morphologies.
Bibliography:ArticleID:MAME565
istex:1FE33183E8EF6F2CFD637E6CCDC19D1C05FD86CD
ark:/67375/WNG-2VV08178-1
ISSN:1438-7492
1439-2054
DOI:10.1002/1439-2054(20011001)286:10<565::AID-MAME565>3.0.CO;2-E