Well-defined polymer microspheres formed by living dispersion polymerization: precisely functionalized crosslinked polymer microspheres from monomers possessing cumulated double bonds

The precise method for synthesizing well-defined polymer microspheres via π-allylnickel-catalyzed living coordination polymerization of allene derivatives under dispersion polymerization conditions is described. The π-allylnickel-catalyzed living coordination polymerization of allene derivatives suc...

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Bibliographic Details
Published in:NPG Asia materials 2016-09, Vol.8 (9), p.e307-e307
Main Authors: Yamauchi, Akira, Shirai, Aya, Kawabe, Kazunari, Iwamoto, Tadashi, Wakiya, Takeshi, Nishiyama, Hiroki, Inagi, Shinsuke, Tomita, Ikuyoshi
Format: Article
Language:English
Subjects:
639/301/923/1028
639/638/455/941
Allene
Biomaterials
Chemistry and Materials Science
Crosslinking
Derivatives
Dispersion
Energy Systems
Materials Science
Microspheres
Monomers
Optical and Electronic Materials
original-article
Polymerization
Solvents
Structural Materials
Surface and Interface Science
Thin Films
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Summary:The precise method for synthesizing well-defined polymer microspheres via π-allylnickel-catalyzed living coordination polymerization of allene derivatives under dispersion polymerization conditions is described. The π-allylnickel-catalyzed living coordination polymerization of allene derivatives such as phenoxyallene was carried out in protic solvents such as methanol in the presence of stabilizers such as polyvinylpyrrolidone to produce polymer microspheres with a narrowly dispersed diameter distribution ( D w / D n ) at a high yield. For example, polymer microspheres with a number-average diameter ( D n ) of 1.10 μm and D w / D n of 1.01 were obtained at a yield of 97%; these microspheres are composed of a polymer with a controlled molecular weight ( M n =11 700) and narrow molecular weight distribution ( M w / M n =1.06). The size of the resulting polymer microspheres proved to be affected by polymerization conditions such as the initial monomer concentrations, monomer structures, polymerization media and stabilizers. Unlike conventional dispersion polymerization systems, the use of a bifunctional monomer, 1,4-diallenoxybenzene, for this living dispersion polymerization successfully produced well-defined crosslinked living polymer microspheres that exhibited high solvent tolerance. The postpolymerization of functional allene monomers in the living dispersion polymerization was also successful, resulting in functionalized polymer microspheres that could be applied in solid-phase organic synthesis and solid-supported transition metal catalysis. Polymer microspheres: better chemistry through living reactions A controllable process for producing uniform, robust microspheres can make mixed solid-liquid chemical reactions easier to perform. Tiny beads of polymers such as polystyrene are finding increasing use as supports for catalysts in organic synthesis. Now, Ikuyoshi Tomita from the Tokyo Institute of Technology and co-workers have used a ‘living’ coordination mechanism, which polymerizes molecules until directed to stop, to improve the size distribution and modification capabilities of microspheres. Nickel-based catalysts and unsaturated, bifunctional carbon reagents worked together to generate microspheres with cross-linked internal structures for additional strength and solvent tolerance. Furthermore, the microsphere surfaces contained living, growing ends that can attach to additional reagents. Synthetic trials revealed that decorating the microspheres
ISSN:1884-4049
1884-4057
1884-4057
DOI:10.1038/am.2016.123