Graphite intercalation compounds as anionic polymerization initiators
Identifieur interne : 00ED30 ( Main/Exploration ); précédent : 00ED29; suivant : 00ED31Graphite intercalation compounds as anionic polymerization initiators
Auteurs : J. Gole [France] ; G. Merle [France] ; J. P. Pascault [France]Source :
- Synthetic Metals [ 0379-6779 ] ; 1982.
English descriptors
- Teeft :
- Active centers, Active centres, Alkali graphitides, Alkali metals, Alkyl amines, Amine, Anionic polymerization, Anionic polymerizations, Bulk polymerization, Catalyst efficiency, Cation, Cationic polymerization, Ceylon, Chem, Chemical properties, Complexing, Complexing agent, Complexing agents, Complexing molecule, Copolymer, Copolymerization, Crystalline lattice, Cyclohexane, Diene monomers, Different temperatures, Diffusion phenomena, Diffusion rate, Ethylene, Ethylene oxide, Ethylene oxide polymerization, Experimental data, First stage, Free ions, Good initiators, Graphite, Graphite intercalation, Graphite layer, Graphite layers, Graphite layers increases, Graphite planes, Graphitide, Graphitides, Heterogeneous mechanism, High content, High initiator efficiency, High yields, Homogeneous conditions, Homogeneous media, Homogeneous medium, Homogeneous polymerization, Hydrocarbon solvents, Initiation step, Initiator, Initiator efficiency, Insertion, Intercalation, Intercalation compounds, Interesting results, Interlayer, Interlayer space, Interlayer spacing, Isoprene, Isoprene ceylon, Isoprene madagascar, Isoprene polymerization, Kinetic study, Lamellar, Lamellar compound, Lamellar compounds, Large number, Layer, Lithium, Lithium graphitides, Macromolecular chains, Macromolecule, Madagascar, Madagascar graphite, Merle, Microstructure, Microstructures, Molecular weight, Molecular weights, Monomer, Other hand, Oxide, Panayotov, Pascault, Pham, Polar solvents, Polyisoprene microstructures, Polym, Polymer, Polymerization, Polymerization proceeds, Polymerization rate, Polymerization time, Propagation rate, Rapid stage, Rashkov, Reaction rate, Reaction temperature, Reaction time, Room temperature, Secondary reactions, Slow stage, Solvent, Specific copolymerization, Stereospecific homopolymerization, Straight line, Strong interaction, Strong interactions, Styrene, Styrene ceylon, Styrene content, Synthetic metals, Tacticity, Temperature increases, Termination reaction, Ternary, Tetrahydrofuran, Thermal agitation, Trans.
Abstract
Abstract: The graphite intercalation compounds of alkali metals, both binary (alkali graphitides) and tenary (graphitides solvated by organic molecules), are anionic polymerization initiators; the descriptive aspect is reviewed.Using kinetic observations (polymerization of styrene and isoprene initiated by LiC12, or of ethylene oxide by KC24, or polymerization-depolymerization equilibria) it is shown that the propagation rate constants are slower than in homogeneous media, and that the efficiency of the initiator depends on the kind of monomer or graphite and the influence of the diffusion phenomena in the interlayer spacing of the lamellar compound during the course of polymerization.The study of microstructure and tacticity of polymers and copolymers explains how the graphite layers play a part in the polymerization mechanism, leading to new properties of the graphitides as initiators: •-protection of the live end which can show high tacticity and slow down some secondary reactions;•-a new coordination with one or two graphite layers in addition to diffusion phenomena able to select one monomer among several for a specific copolymerization;•-a configuration of a given monomer for a stereospecific homopolymerization.Finally, alkali graphitides are not only versatile and easy-to-use packed anionic initiators, but also initiators having new specificities.
Url:
DOI: 10.1016/0379-6779(82)90001-7
Affiliations:
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Le document en format XML
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<term>Active centres</term>
<term>Alkali graphitides</term>
<term>Alkali metals</term>
<term>Alkyl amines</term>
<term>Amine</term>
<term>Anionic polymerization</term>
<term>Anionic polymerizations</term>
<term>Bulk polymerization</term>
<term>Catalyst efficiency</term>
<term>Cation</term>
<term>Cationic polymerization</term>
<term>Ceylon</term>
<term>Chem</term>
<term>Chemical properties</term>
<term>Complexing</term>
<term>Complexing agent</term>
<term>Complexing agents</term>
<term>Complexing molecule</term>
<term>Copolymer</term>
<term>Copolymerization</term>
<term>Crystalline lattice</term>
<term>Cyclohexane</term>
<term>Diene monomers</term>
<term>Different temperatures</term>
<term>Diffusion phenomena</term>
<term>Diffusion rate</term>
<term>Ethylene</term>
<term>Ethylene oxide</term>
<term>Ethylene oxide polymerization</term>
<term>Experimental data</term>
<term>First stage</term>
<term>Free ions</term>
<term>Good initiators</term>
<term>Graphite</term>
<term>Graphite intercalation</term>
<term>Graphite layer</term>
<term>Graphite layers</term>
<term>Graphite layers increases</term>
<term>Graphite planes</term>
<term>Graphitide</term>
<term>Graphitides</term>
<term>Heterogeneous mechanism</term>
<term>High content</term>
<term>High initiator efficiency</term>
<term>High yields</term>
<term>Homogeneous conditions</term>
<term>Homogeneous media</term>
<term>Homogeneous medium</term>
<term>Homogeneous polymerization</term>
<term>Hydrocarbon solvents</term>
<term>Initiation step</term>
<term>Initiator</term>
<term>Initiator efficiency</term>
<term>Insertion</term>
<term>Intercalation</term>
<term>Intercalation compounds</term>
<term>Interesting results</term>
<term>Interlayer</term>
<term>Interlayer space</term>
<term>Interlayer spacing</term>
<term>Isoprene</term>
<term>Isoprene ceylon</term>
<term>Isoprene madagascar</term>
<term>Isoprene polymerization</term>
<term>Kinetic study</term>
<term>Lamellar</term>
<term>Lamellar compound</term>
<term>Lamellar compounds</term>
<term>Large number</term>
<term>Layer</term>
<term>Lithium</term>
<term>Lithium graphitides</term>
<term>Macromolecular chains</term>
<term>Macromolecule</term>
<term>Madagascar</term>
<term>Madagascar graphite</term>
<term>Merle</term>
<term>Microstructure</term>
<term>Microstructures</term>
<term>Molecular weight</term>
<term>Molecular weights</term>
<term>Monomer</term>
<term>Other hand</term>
<term>Oxide</term>
<term>Panayotov</term>
<term>Pascault</term>
<term>Pham</term>
<term>Polar solvents</term>
<term>Polyisoprene microstructures</term>
<term>Polym</term>
<term>Polymer</term>
<term>Polymerization</term>
<term>Polymerization proceeds</term>
<term>Polymerization rate</term>
<term>Polymerization time</term>
<term>Propagation rate</term>
<term>Rapid stage</term>
<term>Rashkov</term>
<term>Reaction rate</term>
<term>Reaction temperature</term>
<term>Reaction time</term>
<term>Room temperature</term>
<term>Secondary reactions</term>
<term>Slow stage</term>
<term>Solvent</term>
<term>Specific copolymerization</term>
<term>Stereospecific homopolymerization</term>
<term>Straight line</term>
<term>Strong interaction</term>
<term>Strong interactions</term>
<term>Styrene</term>
<term>Styrene ceylon</term>
<term>Styrene content</term>
<term>Synthetic metals</term>
<term>Tacticity</term>
<term>Temperature increases</term>
<term>Termination reaction</term>
<term>Ternary</term>
<term>Tetrahydrofuran</term>
<term>Thermal agitation</term>
<term>Trans</term>
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<front><div type="abstract" xml:lang="en">Abstract: The graphite intercalation compounds of alkali metals, both binary (alkali graphitides) and tenary (graphitides solvated by organic molecules), are anionic polymerization initiators; the descriptive aspect is reviewed.Using kinetic observations (polymerization of styrene and isoprene initiated by LiC12, or of ethylene oxide by KC24, or polymerization-depolymerization equilibria) it is shown that the propagation rate constants are slower than in homogeneous media, and that the efficiency of the initiator depends on the kind of monomer or graphite and the influence of the diffusion phenomena in the interlayer spacing of the lamellar compound during the course of polymerization.The study of microstructure and tacticity of polymers and copolymers explains how the graphite layers play a part in the polymerization mechanism, leading to new properties of the graphitides as initiators: •-protection of the live end which can show high tacticity and slow down some secondary reactions;•-a new coordination with one or two graphite layers in addition to diffusion phenomena able to select one monomer among several for a specific copolymerization;•-a configuration of a given monomer for a stereospecific homopolymerization.Finally, alkali graphitides are not only versatile and easy-to-use packed anionic initiators, but also initiators having new specificities.</div>
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