Processing-Structure-Properties Relationships in Polymers

doi:10.3390/books978-3-03921-881-3

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carbon nanotube; homogeneous dispersion; ethylene vinyl acetate; mechanical performance; electrical conductivity; microencapsulation; melamine polyphosphate; polyurethane; composite; flame retardant; biodegradable nanofibers; PLGA; collagen; epinephrine; lidocaine; polyimide film; linear coefficient of thermal expansion (CTE); copper clad laminate; structure and properties; polymorphism; isotactic polypropylene; deformation; phase transitions; uniaxial compression; uniaxial tensile deformation; temperature; in situ X-ray; cavitation; indentation; Harmonix AFM; polymer morphology; mechanical properties; ultra-high molecular weight polyethylene (UHMWPE); microcellular injection molding; supercritical fluid; supercritical N₂; supercritical CO₂; tissue engineering and regenerative medicine; bioresorbable polymers; 3D printing/additive manufacturing; fused filament fabrication/fused deposition modelling; degradation; physicochemical characterization; polycaprolactone; layered double hydroxides; ionic liquids; PLA; reactive blending; biobased films; graphene; nanoreinforcement; curing rate; epoxy microstructure; fatigue; composites; critical gel; poly(lactic acid); carbon black; graphite; polymer blend; poly(ethylene terephthalate); intrinsic viscosity; polyolefin; compatibilizer; isotactic polypropylene; stress-induced phase transitions; structural analysis; X-ray diffraction; polyoxymethylene (POM); octakis[(3-glycidoxypropyl)dimethylsiloxy]octasilsesquioxane (GPOSS); composites; morphology; mechanical properties; conductive filler; orientation; conductive polymer composites; foam; model; PLLA; bioresorbable vascular scaffolds; stretch blow molding; biaxial elongation; SAXS; WAXS; microfibrillar composites; crystalline morphology; crystallinity; mechanical properties; crystallisation; morphology; nanoparticles; shear; flow; orientation; poly(ε-caprolactone); polyvinyl butyral; hydrophobicity; contact angle; polypropylene; atomic force microscopy; injection molding; mold temperature evolution; polycaprolactone; ultra-high molecular weight polyethylene; incremental forming; SPIF; XRD; chain orientation; temperature sensitive; gel; controllable gas permeability; breathable film; polymer composite; processing; polyamide 6; compression molding; polymorphism; polyamide 6; injection molding; polymorphism; humidity; mechanical properties

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Processing-Structure-Properties Relationships in Polymers

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December 2019

400 pages

ISBN978-3-03921-880-6 (Paperback)
ISBN978-3-03921-881-3 (PDF)

https://doi.org/10.3390/books978-3-03921-881-3

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This is a Reprint of the Special Issue Processing-Structure-Properties Relationships in Polymers that was published in

Chemistry & Materials Science

Engineering

Summary

This collection of research and review papers is aimed at depicting the state of the art on the possible correlations between processing variables, obtained structure and special properties which this structure induces on the plastic part. The extraordinary capacity of plastics to modify their properties according to a particular structure is evidenced for several transformation processes and for many applications. The final common goal is to take profit of this peculiar capacity of plastics by inducing, through a suitable processing, a specific spatial organization.

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Processing-Structure-Properties Relationships in Polymers

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