Clay-Polymer Nanocomposites
Clay?Polymer Nanocomposites is a complete summary of the existing knowledge on this topic, from the basic concepts of synthesis and design to their applications in timely topics such as high-performance composites, environment, and energy issues. This book covers many aspects of synthesis such as in- situ polymerization within the interlamellar spacing of the clays or by reaction of pristine or pre-modified clays with reactive polymers and prepolymers. Indeed, nanocomposites can be prepared at industrial scale by melt mixing. Regardless the synthesis method, much is said in this book about the importance of theclay pre-modification step, which is demonstrated to be effective, on many occasions, in obtaining exfoliated nanocomposites.
Clay?Polymer Nanocomposites reports the background to numerous characterization methods including solid state NMR, neutron scattering, diffraction and vibrational techniques as well as surface analytical methods, namely XPS, inverse gas chromatography and nitrogen adsorption to probe surface composition, wetting and textural/structural properties. Although not described in dedicated chapters, numerous X-ray diffraction patterns of clay?polymer nanocomposites and reference materials are displayed to account for the effects of intercalation and exfoliations of layered aluminosilicates. Finally, multiscale molecular simulation protocols are presenting for predicting morphologies and properties of nanostructured polymer systems with industrial relevance.
As far as applications are concerned, Clay?Polymer Nanocomposites examines structural composites such as clay?epoxy and clay?biopolymers, the use of clay?polymer nanocomposites as reactive nanocomposite fillers, catalytic clay-(conductive) polymers and similar nanocomposites for the uptake of hazardous compounds or for controlled drug release, antibacterial applications, energy storage, and more.
1. Overview of clay preparation, properties, and modification2. Overview of clay/polymer nanocomposites3. Multiscale molecular modelling of clay/polymer nano composites4. Design of clay/polymer nanocomposites by mixing5. Chemical and photochemical routes towards tailor-made polymer/clay nanocomposites: recent progress and future prospects6. Conductive polymer/clay nanocomposites7. Bionanocomposites8. Organo - Clay Hybrid Films with Improved Functionality9. NMR Spectroscopy of Clay Polymer Nanocomposites10. Neutron scattering on different states of polymer/clay compounds: From solution to dry states11. Surface analysis of clay/polymer nanocomposites12. Recent Advancement towards Dynamic Mechanical Analysis of Clay-Polymer Nanocomposites13. Flame retardant properties of clay/polymer14. Clay/polymer nanocomposites for controlled drug release
Mohamed M. Chehimi is the Research Director at French CNRS. He obtained a PhD in Physical Organic Chemistry at the University Paris Diderot in 1988, and joined CNRS in 1989 for a permanent researcher position. He has been promoted Research Director Grade 1 (DR1) in 2011. His research topics include the design of reactive and functional polymer and nanocomposite coatings. In the recent years he has spent time and effort developing aryldiazonium salts as new coupling agents in materials science. The applications encompass adsorbents, electrochemical sensors, fillers, antibacterial surfaces and electronic devices. He is also a specialist of XPS analysis of a broad range of materials including polymer composites. He has published over 250 research papers and 20 book chapters. He is the editor of three books and g
- The most comprehensive coverage of the state of the art in clay–polymer nanocomposites, from synthesis and design to opportunities and applications
- Covers the various methods of characterization of clay–polymer nanocomposites - including spectroscopy, thermal analyses, and X-ray diffraction
- Includes a discussion of a range of application areas, including biomedicine, energy storage, biofouling resistance, and more
Date de parution : 07-2017
Ouvrage de 546 p.
19x23.3 cm
Mots-clés :
�Grafting to� and �grafting from� Auger electron; Bentonite; Biocompatibility; Biodegradability; Bionanocomposites; C; Carbon nanotubes; Cation exchange capacity; Clay nanocomposites; Clay-dye hybrid films; Clay-polymer nanocomposites; Clay/ICP nanocomposites; Clay; Clays; Click chemistry; Coarse-grained simulations; Compatibilizers; Composites; Cone calorimeter; Confined polymers; Contact angle measurements; Controlled radical polymerization; Cross-polarization; Diffuse reflectance infrared Fourier transform; Drug delivery systems; Dynamic mechanical analysis; Electrospinning; Exfoliated morphology; Finite element; Flame retardants; Hectorite; High-power decoupling; Hydroxyapatite; Infrared spectroscopy; Inherently conductive polymers; In-situ polymerization; Inverse gas chromatography; Kaolinite; Langmuir-Blodgett; Laponite; lay; Layer-by-layer technique; Magic-angle spinning; methodologies; Mixing; Montmorillonite; Morphology; Multiscale molecular modeling; Nanoclay; Nanocomposite; Nanocomposites; Nanofiller; Neutron spin echo; Organoclay; Organomodified montmorillonites; Organomodifiers; Organosilane; Photopolymerization; Polyaniline; Polymer nanocomposites; Polymer scattering; Polymer-clay nanocomposites; Polymer; Polypyrrole; Polythiophene; Pyrolysis combustion flow calorimeter; Rectorite; Rheological properties; Sepiolite; Smectite; Solid-state nuclear magnetic resonance spectroscopy; Spin coating; Spin-lattice relaxation time; Spin-spin relaxation time; Surface-initiated polymerization; Swelling; The barrier effect; Thermoplastic polyurethane; Thermoplastic; Thermoset; Time of flight-secondary ion mass spectroscopy; Toxicity; Viscoelastic properties; X-ray photoelectron spectroscopy; X-ray scattering
