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010   $a9786611309145
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100   $a20070404d2007      uy             0
101 0 $aeng
135   $aurcn|||||||||
181   $ctxt
182   $cc
183   $acr
200 00$aPolymer reaction engineering$b[electronic resource] /$fedited by Jose? M. Asua
210   $aOxford ;$aAmes, Iowa $cBlackwell Pub.$d2007
215   $a1 online resource (394 p.)
300   $aDescription based upon print version of record.
311   $a1-4051-4442-4 
320   $aIncludes bibliographical references and index.
327   $aPolymer Reaction Engineering; Contents; Contributors; Preface; Notation; Acronyms; 1 Introduction to Polymerization Processes; 1.1 Microstructural features of polymers and their effect on properties; 1.1.1 Chemical composition and monomer sequence distribution; 1.1.2 Molecular weight distribution; 1.1.3 Polymer architecture; 1.1.4 Chain configuration; 1.1.5 Morphology; 1.1.6 Effect of processing and compounding on the microstructure of the polymeric materials; 1.2 Classes of polymerizations; 1.2.1 Chain-growth polymerization; 1.2.2 Step-growth polymerization; 1.3 Polymerization techniques
327   $a1.4 Main commercial polymers 1.4.1 Polyolefins; 1.4.2 Styrenic polymers; 1.4.3 Poly(vinyl chloride); 1.4.4 Waterborne dispersed polymers; 1.4.5 Polyesters and polyamides; 1.4.6 Thermosets; 1.5 Polymerization reactors; References; 2 Coordination Polymerization; 2.1 Polyolefin types: microstructural classification and analytical techniques; 2.1.1 Polyethylene types; 2.1.2 Polypropylene types; 2.1.3 Polyolefin microstructural characterization techniques; 2.2 Catalysts for olefin polymerization; 2.2.1 Coordination catalyst types; 2.2.2 Polymerization mechanism
327   $a2.3 Polymerization kinetics for single- and multiple-site catalysts 2.3.1 Homopolymerization; 2.3.2 Copolymerization; 2.3.3 Long-chain branch formation; 2.4 Inter- and intraparticle mass and heat transfer resistances; 2.4.1 Particle fragmentation and morphology control; 2.4.2 Single particle models: inter- and intraparticle mass and heat transfer; 2.5 Industrial olefin polymerization reactors; 2.5.1 Reactor configurations and designs; 2.5.2 Polyethylene manufacturing processes; 2.5.3 Polypropylene manufacturing processes; 2.5.4Mathematical models for industrial reactors; Acknowledgments
327   $aReferences 3 Free-Radical Polymerization: Homogeneous Systems; 3.1 Free-radical polymers: properties and applications; 3.2 FRP mechanisms and kinetics; 3.2.1 Homopolymerization; 3.2.2 Copolymerization; 3.2.3 Diffusion-controlled reactions; 3.2.4 Kinetic balances for modeling polymer MWs; 3.3 Controlled radical polymerization; 3.3.1 Stable free-radical polymerization; 3.3.2 Atom transfer radical polymerization; 3.3.3 Reverse addition-fragmentation chain transferpolymerization; 3.4 Polymer reaction engineering aspects; 3.4.1 Heat removal and temperature programming; 3.4.2 Batch reactors
327   $a3.4.3 Semibatch (semicontinuous) reactors 3.4.4 Continuous stirred-tank reactors; 3.4.5 Tubular reactors; 3.5 A ""roadmap"" for mathematical modeling; References; 4 Free-Radical Polymerization: Heterogeneous Systems; 4.1 Introduction; 4.2 High-impact polystyrene; 4.2.1 Interrelationship between microstructure and application properties; 4.2.2 Modeling HIPS polymerization; 4.2.3 Optimizing final properties: melt flow index in a continuous HIPS process; 4.2.4 Final remarks for HIPS; 4.3 Vinyl chloride monomer bulk polymerization; 4.3.1 Kinetic mechanism; 4.3.2 PVC morphology; Acknowledgments
327   $aReferences
330   $aPolymers are an example of ""products-by-process"", where the final product properties are mostly determined during manufacture, in the reactor. An understanding of processes occurring in the polymerization reactor is therefore crucial to achieving efficient, consistent, safe and environmentally friendly production of polymeric materials.Polymer Reaction Engineering provides the link between the fundamentals of polymerization kinetics and polymer microstructure achieved in the reactor. Organized according to the type of polymerization, each chapter starts with a description of the main
606   $aPolymerization
606   $aPolymer engineering
615  0$aPolymerization.
615  0$aPolymer engineering.
676   $a668.9/2
701   $aAsua$b Jose? M$0962718
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910145584603321
996   $aPolymer reaction engineering$92182933
997   $aUNINA