Search results for "Addition polymer"

showing 10 items of 114 documents

Carbanions on Tap – Living Anionic Polymerization in a Microstructured Reactor

2008

The paper describes the living anionic polymerization of styrenes to homo- and diblock copolymers in continuous flow, using a microstructured mixing set-up ("microreactor"). Reaction times and experimental effort are significantly reduced compared to classical batch methods that often require stringent reaction conditions and strict drying of the apparatus by "break-seal" and "high vacuum" techniques. In continuous flow, residual impurities can be removed by purging the reactor with monomer and initiator solution before polymer samples are collected at the device outlet on a scale of up to 200 g.h -1 . Facile molecular weight adjustment is achieved by variation of the flow rates of initiato…

Materials sciencePolymers and PlasticsBulk polymerizationOrganic ChemistryDispersitySolution polymerizationCondensed Matter Physicschemistry.chemical_compoundMonomerAnionic addition polymerizationPolymerizationchemistryPolymer chemistryMaterials ChemistryCopolymerPhysical and Theoretical ChemistryLiving anionic polymerizationMacromolecular Chemistry and Physics
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Synthesis of block copolymers with poly(methyl methacrylate): P(B-b-MMA), P(EB-b-MMA), P(S-b-B-b-MMA) and P(S-b-EB-b-MMA)

1993

Well-defined diblock copolymers poly(butadiene-b-methyl methacrylate) (=P(B-b-MMA)) and triblock copolymers poly(styrene-b-butadiene-b-methyl methacrylate) (=P(S-b-B-b-MMA)) have been prepared by sequential anionic polymerization in THF. The synthesis of P(B-b-MMA) and P(S-b-B-b-MMA) was most efficient in the presence of lithium alkoxides. By this method side reactions are suppressed and the polymerization can be performed at higher temperatures. The resulting triblock copolymers have narrow molecular weight distribution. The 1,2-PB midblock was quantitatively hydrogenated with tosylhydrazide to enhance thermal stability. Alternatively the hydrogenation can be performed at elevated pressure…

Materials sciencePolymers and PlasticsButanoneGeneral ChemistryCondensed Matter PhysicsMethacrylatePoly(methyl methacrylate)chemistry.chemical_compoundAnionic addition polymerizationchemistryPolymerizationvisual_artAlkoxidePolymer chemistryMaterials ChemistryCopolymervisual_art.visual_art_mediumMolar mass distributionPolymer Bulletin
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A contribution to the kinetics of the polymerization of styrene with CF3SO3H as catalyst

1978

The time dependence of the cationic polymerization of styrene in CH2Cl2 with CF3SO3H as catalyst can be formally described as being first-order with respect to monomer concentration [M]0. The reaction rate shows a third-order dependence in catalyst concentration [C]0. A high polymer and a low polymer polystyrene fraction are found at [M]0>0.2 mole · l−. The reaction rate of the high polymer fraction is proportional to [C] 0 3 , that of the low polymer fraction probably proportional to [C] 0 2 . The polymerization active species may thus be triple ions in the first and ion pairs in the second case.

Materials sciencePolymers and PlasticsCationic polymerizationSolution polymerizationGeneral ChemistryCondensed Matter PhysicsStyrenechemistry.chemical_compoundMonomerChain-growth polymerizationchemistryPolymerizationPolymer chemistryMaterials ChemistryAddition polymerPolystyrenePolymer Bulletin
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Linear-Hyperbranched Amphiphilic AB Diblock Copolymers Based on Polystyrene and Hyperbranched Polyglycerol

2005

A convenient three-step strategy has been developed for the preparation of well-defined amphiphilic, linear hyperbranched block copolymers by hypergrafting. The synthetic procedure is based on a combination of carbanionic polymerization with the alkoxide-based controlled ring-opening multibranching polymerization of glycidol. A linear AB diblock copolymer polystyrene-block-polybutadiene (PS-b-PB) with narrow polydispersity was obtained by anionic copolymerization. Subsequent hydroxylation by hydroboration led to PS 508 -b-(PB-OH) 56 , used as macro--initiator for the polymerization of glycidol under slow monomer addition conditions.

Materials sciencePolymers and PlasticsOrganic ChemistryDispersityGlycidolRing-opening polymerizationchemistry.chemical_compoundMonomerAnionic addition polymerizationchemistryPolymerizationPolymer chemistryMaterials ChemistryCopolymerPolystyreneMacromolecular Rapid Communications
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Temperature Variation Enables the Design of Biobased Block Copolymers via One‐Step Anionic Copolymerization

2021

A one-pot approach for the preparation of diblock copolymers consisting of polystyrene and polymyrcene blocks is described via a temperature-induced block copolymer (BCP) formation strategy. A monomer mixture of styrene and myrcene is employed. The unreactive nature of myrcene in a polar solvent (tetrahydrofuran) at -78 °C enables the sole formation of active polystyrene macroinitiators, while an increase of the temperature (-38 °C to room temperature) leads to poly(styrene-block-myrcene) formation due to polymerization of myrcene. Well-defined BCPs featuring molar masses in the range of 44-117.2 kg mol-1 with dispersities, Ð, of 1.09-1.21, and polymyrcene volume fractions of 30-64% are acc…

Materials sciencePolymers and PlasticsPolymers02 engineering and technology010402 general chemistry01 natural sciencesPolymerizationStyrenechemistry.chemical_compoundMaterials ChemistryCopolymerMolar massOrganic ChemistryTemperature021001 nanoscience & nanotechnology0104 chemical sciencesMolecular WeightMonomerAnionic addition polymerizationchemistryChemical engineeringPolymerizationPolystyrenesSelf-assemblyPolystyrene0210 nano-technologyMacromolecular Rapid Communications
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Synthesis, characterization and properties of functional star and dendritic block copolymers of ethylene oxide and glycidol with oligoglycidol branch…

2009

Abstract Well-defined, four-arm star block copolymers of ethylene oxide and glycidol were prepared via controlled anionic polymerization using protected glycidol. The length of the poly(ethylene oxide) block was varied from DP = 10 to 50, while the length of the short polyglycidol block remained nearly constant, at DP = 4–6. Star block copolymers with hydroxyl groups at the ends of the arms after conversion to the corresponding alkoxides were used as multifunctional macroinitiators for the sequential polymerization of ethylene oxide and protected glycidol. After deprotection, the branched block copolymers of ethylene oxide and glycidol had narrow molar mass distributions and multiple hydrox…

Molar massMaterials sciencePolymers and PlasticsEthylene oxideOrganic ChemistryGlycidolBranching (polymer chemistry)chemistry.chemical_compoundAnionic addition polymerizationchemistryPolymerizationDendrimerPolymer chemistryMaterials ChemistryCopolymerPolymer
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1993

Nitroxide mediated radical polymerizationAnionic addition polymerizationPolymerizationChemistryPolymer chemistryRadical polymerizationChain transferReversible addition−fragmentation chain-transfer polymerizationPhotochemistryIonic polymerizationLiving anionic polymerizationDie Makromolekulare Chemie, Rapid Communications
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Effect of Lithium Perchlorate on the Kinetics of the Anionic Polymerization of Methyl Methacrylate in Tetrahydrofuran

1999

The kinetics of the anionic polymerization of methyl methacrylate in the presence of lithium perchlorate (LiClO 4 ) are investigated in THF using 1,1-diphenylhexyllithium as initiator in a flow-tube reactor between -30 and 0 °C. The rate constants of propagation determined in the presence of LiClO 4 are lower than those obtained in the absence of the salt, similar to the effect observed for LiCl. For propagation, the reaction order with respect to active center concentration is found to be 0.5 in both cases, which indicates that LiClO 4 does not effectively perturb the aggregation of the enolate ion pair. The formation of various mixed aggregates is proposed. The polydispersity index of the…

Order of reactionPolymers and PlasticsOrganic ChemistryInorganic chemistryKineticsSolution polymerizationLithium perchlorateInorganic Chemistrychemistry.chemical_compoundAnionic addition polymerizationReaction rate constantchemistryMaterials ChemistryMethyl methacrylateTetrahydrofuranMacromolecules
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Mechanism of Anionic Polymerization of (Meth)acrylates in the Presence of Aluminium Alkyls IV. Formation of a Co-ordinative Polymer Network via the L…

1996

The polymerization of methyl methacrylate in the presence of aluminium alkyls in toluene deviates from conventional kinetics. This results predominantly from the formation and precipitation of a co-ordinative polymer gel or network. Due to the lower reactivity and accessibility of the living chains in the gel, they are regarded as ’dormant’ and thus the concentration of active species decreases during polymerization. The network formation occurs via co-ordination of the living aluminate chain end group with in-chain ester carbonyl groups. Part of the chains are deactivated by a termination process but they are free of cyclic β-ketoesters which would result from the common ’back-biting’ reac…

Polymers and PlasticsChemistryAluminateSolution polymerizationPoly(methyl methacrylate)End-groupchemistry.chemical_compoundAnionic addition polymerizationPolymerizationvisual_artPolymer chemistryMaterials Chemistryvisual_art.visual_art_mediumLiving polymerizationLiving anionic polymerizationPolymer Journal
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Polymerization of styrene

1979

Polymers and PlasticsChemistryChain transferGeneral ChemistryCondensed Matter PhysicsChain-growth polymerizationAnionic addition polymerizationPolymerizationPolymer chemistryMaterials ChemistryCopolymerLiving polymerizationReversible addition−fragmentation chain-transfer polymerizationIonic polymerizationPolymer Bulletin
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