Polyvinyl chloride and polyethylene polymers, which have long been the mainstay of industrial polymers, are now making way for new high performance polymers. Engineering plastics are polymers that have various properties designed into the polymer. For example, some polymers are designed for thermal resistance, such as polyamide, and polycarbonate, which are widely used these days. The thermal resistance of a polymer is determined by the softening point, as the softening point rises with the increase in the material strength. To make improvements in the softening points and material strength, the super engineering plastics such as polysulfone, polyether sulfone, polyarylate and polyimide have been developed. The softening points of these polymers are all above 150 ºC, and these utilized in materials of fireman uniform and bulletproof vest, and so on. Active R&D is continuing to take place to further improve the performance.1)
On the other hand, there have been active experiments in adding new functions to the polymers, such as the electrical, optical, medical and biological properties. For example, copolymers which are obtained by the polymerization of fluorine containing monomers and variety of monomers have been utilized as photoresists, optical fiber dressings, oxygen enrichment membranes, and membrane oxygenators. Polysilane has the maximum absorption in the ultraviolet region, and also has photosensitivity; therefore, it can be used as a positive type resist with excellent oxygen plasma resistance.2) Polylactic acid (PLA) has been commercialized as an environmentally-friendly polymer, being compatible with the natural environment. Furthermore, it can save fossil resources as it is made of biomass raw materials.3)
Further broad applications are expected to be made with functional polymers, thus R&D in this field is highly promising. The page below shows a wide variety of monomers and intermediates as building blocks for functional polymers. These are surely useful for the development of novel polymers.
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Polymer/Macromolecule Reagents
References
- 1) (a) M. Ishikawa, Shokubai 1990, 32, 203.
- (b) M. Ishikawa, Kobunnshi 1993, 42, 564.
- 2) (a) J. Furukawa, Polymer Digest 1992, 10, 57.
- (b) J. Furukawa, Polymer Digest 1992, 11, 62.
- 3) N. Kawashima, Yuki Gosei Kagaku Kyokaishi (j. Synth. Org. Chem., Jpn.) 2003, 61, 496.
Explore Polymer/Macromolecule Reagents Categories
Aldehyde Linkers [Covalent Organic Frameworks (COFs) Linkers]
Amine Linkers [Covalent Organic Frameworks (COFs) Linkers]
Boronic Acid Linkers [Covalent Organic Frameworks (COFs) Linkers]
Carboxylic Anhydride Linkers [Covalent Organic Frameworks (COFs) Linkers]
Linkers (Others) [Covalent Organic Frameworks (COFs) Linkers]
Acrylic Monomers
Allyl Monomers
Bismaleimide Monomers
Cyclic Olefin Monomers
Diamine Monomers
Dicarboxylic Acid Chloride Monomers
Dicarboxylic Acid Monomers
Diol Monomers
Disulfonyl Chloride Monomers
Dithiol Monomers
Divinyl Monomers, Diallyl Monomers
Epoxide Monomers
Fluorinated Monomers
Isocyanate Monomers
Isothiocyanate Monomers
Lactone Monomers, Lactide Monomers
Oxetane Monomers
Styrene Monomers
Tetracarboxylic Dianhydride Monomers
Vinyl Monomers
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