Keywords:
Polymerization.
;
Polymers.
;
Electronic books.
Description / Table of Contents:
It is well known that polymeric and composite materials are finding various applications in some critical areas of human endeavors, such as medicine, medical appliances, energy and the environment. This edition will, hopefully, evoke interest from scientists working in the fields of chemistry, polymer chemistry, electrochemistry and material science. Its applications and uses include: polymer electrolyte membrane fuel cells, sensors, actuators, coatings, electrochromic and electroluminescent materials, magnetic polymers, organo-metallic polymers, tissue engineering, methods of the immobilization of biological molecules, and dental and orthopedic applications. This edition is a highly valuable source for scientists, researchers, upper-level undergraduate and graduate students, as well as college and university professors, because it provides the most up-to-date reference work summarizing the pioneering research work in the field of polymeric and composite materials.
Type of Medium:
Online Resource
Pages:
1 online resource (372 pages)
Edition:
1st ed.
ISBN:
9781629480619
Series Statement:
Polymer Science and Technology
URL:
https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=2193844
DDC:
620.192
Language:
English
Note:
Intro -- ADVANCED FUNCTIONAL POLYMERS AND COMPOSITES: MATERIALS, DEVICES AND ALLIED APPLICATIONS. VOLUME 1 -- ADVANCED FUNCTIONAL POLYMERS AND COMPOSITES: MATERIALS, DEVICES AND ALLIED APPLICATIONS. VOLUME 1 -- Library of Congress Cataloging-in-Publication Data -- Dedication -- Contents -- Preface -- Contributors -- About the Editor -- Acknowledgments -- Chapter 1: Advances in Membranes for High Temperature Polymer Electrolyte Membrane Fuel Cells -- Abstract -- Abbreviations -- 1. Introduction -- 2. Proton Exchange Membrane Fuel Cells (PEMFCS) -- 2.1. Role of Proton Conducting Membrane in Proton Exchange Membrane Fuel Cells -- 2.2. Requirement for Proton Conducting Membrane for Proton Exchange Membrane Fuel Cells -- 2.3. Current Status of Perfluorinated Sulfonic Acid and Alternative Proton Conducting Membranes -- 2.4. Proton Transport in Sulfonic Acid Membranes -- 2.5. Challenges Facing Sulfonic Acid Membranes in Proton Exchange Membrane Fuel Cells -- 3. High Temperature Polymer Electrolyte -- Membrane Fuel Cell -- 3.1. Proton Exchange Membranes for High Temperature Proton Exchange Membrane Fuel Cells -- 3.2. Membranes Obtained by Modification with Hygroscopic Inorganic Fillers -- 3.3. Membranes Obtained by Modification with Solid Proton Conductors -- 3.4. Membranes Obtained by Modification with Less Volatile Proton Assisting Solvent -- 3.4.1. Doping with Heterocyclic Solvents -- 3.4.2. Doping with Phosphoric Acid -- 3.4.3. Radiation Grafted and Acid Doped Membranes -- 3.5. Disadvantages of Using Phosphoric Acid Composite Membranes for High Temperature Proton Exchange Membrane Fuel Cell Applications -- 3.6. Alternative Membranes Based on Benzimidazole Derivatives -- 3.7. Alternative Benzimidazole Polymers Doped with Heteropoly Acids -- 3.8. Membrane Impregnated with Ionic Liquids -- 3.9. Summary of Membranes Obtained by Modification of Sulfonic.
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Acid Ionomers -- 4. Proton Conduction Mechanism in High Temperature Proton Conducting Membrane -- Conclusion and Prospectives -- Acknowledgments -- References -- Chapter 2: Surface-Confined Ruthenium and Osmium Polypyridyl Complexes as Electrochromic Materials -- Abstract -- Abbreviations -- 1. Introduction -- 1.1. Electrochromic Windows, Displays and Mirrors -- 1.2. Classes of Electrochromic Materials -- 1.3. Metal Complexes As Electrochromic Materials -- 1.3.1. Ruthenium (II) Complexes As Electrochromic Materials -- (I). Optical Behavior of Ruthenium Complexes -- (II). Redox Behavior of Ruthenium Complexes -- (III). Role of Spacers in Dinuclear Ruthenium Complexes -- 1.3.2. Osmium (II) Complexes As Electrochromic Materials -- 1.3.3. Other Metal Complexes As Electrochromic Materials -- 1.4. Substrates Used for Electrochromic Material -- 1.5. Modification of Substrates -- 2. Surface-Confined Ruthenium Complexes -- As Electrochromic Materials -- 2.1. Chemically Adsorbed Ruthenium Complexes -- 2.2. Physically Adsorbed Ruthenium Complexes -- 3. Surface-Confined Osmium Complexes -- As Electrochromic Materials -- 3.1. Osmium Complex-Based Monolayer -- 3.2. Osmium Complex-Based Multilayer -- 4. Surface-Confined Hetero-Metallic -- Complexes As Electrochromic Materials -- 4.1. Coordinative Supramolecular Assembly As Thin Films -- Conclusion -- Acknowledgments -- References -- Chapter 3: Magnetic Polymeric Nanocomposite Materials: Basic Principles Preparations and Microwave Absorption Application -- 1Department of Materials Science, School of Applied Physics, Faculty of Science -- and Technology, Universiti Kebangsaan Malaysia, Bangi, Selangor, Malaysia -- 2Institute of Hydrogen Economy, Universiti Teknologi Malaysia, -- Jalan Semarak, Kuala Lumpur, Malaysia -- Abstract -- Abbreviations -- 1. Introduction -- 2. Historical Background.
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3. Interaction Mechanisms of Electromagnetic Wave -- with Materials -- 3.1. Interaction Mechanism with Conductor Materials -- 3.2. Interaction Mechanism with Dielectric Materials -- 3.3. Interaction Mechanism with Magnetic Materials -- 4. The Reason of Using Microwave Absorbing Materials -- 5. The Criteria for Choosing the Filler and the -- Importance of Matching Conditions for Ideal -- Microwave Absorbing Materials -- 5.1. Metal-Backed Single Layer Absorber Mode -- 5.2. Stand-Alone Absorbing Material Model -- 6. Types and Properties of Polymers -- 7. Magnetic Polymer Nanocomposites -- 7.1. Nanomaterials -- 7.2. Magnetic Polymer Nanocomposites' Properties -- 7.3. Magnetic Polymer Nanocomposites' Applications -- 7.4. The Importance of Dispersion in Magnetic Polymer Nanocomposites -- 8. Preparation and Processing of -- Magnetic Polymer Nanocomposites -- 8.1. In-Situ Oxidative Polymerization Method (with Sonication) -- 8.2. One-Step Chemical Method -- 8.3. Surface-Initiated Polymerization Method -- 8.4. Microemulsion Chemical Oxidative Polymerization Method -- 8.5. Reverse Micelle Microemulsion Method -- 8.6. In-Situ Inverse Microemulsion Polymerization -- 8.7. Irradiation Induced Inverse Emulsion Polymerization -- 8.8. Miniemulsion Polymerization -- 8.9. Mechanical Melt Blending Method -- 8.10. Melt Processing Method Using Ultrasonic Bath -- 8.11. Template Free Method -- 8.12. Solution Casting Method -- 8.13. Sonochemical Method -- 8.14. Electrochemical Synthesis -- 9. Electromagnetic Wave Absorption Application of Magnetic Polymer Nanocomposites -- 9.1. The Crucial Role of Magnetic Nanoparticles and Sample Thickness in the Determination of the Microwave Absorption Application -- 9.2. Effect of Magnetic Filler Size on the Microwave Absorption and/or Electromagnetic Interference Shielding Application.
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9.3. Broadening the Microwave Absorption Range for Low and High Frequency Applications Using Binary Magnetic Nanofillers -- 9.4. The Enhancement of the Microwave Absorption for Electromagnetic Interference Shielding Application Using Magnetic and Dielectric Nanofillers -- Conclusion -- References -- Chapter 4: Polyetheramide-Birth of a New Coating Material -- Abstract -- Abbreviations -- 1. Introduction -- 2. Raw Materials and Test Methods -- 3. Linseed Oil Based Polyetheramides[LPEtA] -- 4. Soybean Oil Based Polyetheramides (SPEtA) -- 5. Albizia Lebbek Benth Oil Based PEtA (ABOPEtA) -- 6. Jatropha Seed Oil Based PEtA(JPEtA) -- 6. Olive Oil Based PEtA (OPEtA) -- Conclusion -- Acknowledgments -- References -- [1] Sørensen, P. A., Kiil,S., Dam-Johansen, K. & -- Weinell, C. E. (2009). Anticorrosive coatings: a review, J. Coat. Technol. Res., 6(2), 135-176. -- Chapter 5: Advanced Functional Polymers and Composite Materials and Their Role in Electroluminescent Applications -- Abstract -- Introduction & -- Scope of the Work -- 1. Light Emitting Diodes (LEDs), Characteristics and Categories -- (a) LED- Device Configuration -- (b) Recent Developments in The LED's Technology -- In-organic Light Emitting Diode -- Materials & -- Characteristics -- 3-I. Luminescence and Scintillation from the Inorganic Phosphor Materials -- An Ideal Luminescencent Material's Characteristics -- 3-II. Scintillation -- 3-III. Inorganic Electroluminescent Materials & -- Devices -- Organic Light Emitting Diodes Devices (OELDs) -- 4- (i). OLED Characteristics -- 4-(ii). OLED- Device Configuration & -- Working Principle -- 4-(iii). General Electroluminescent Materials Used for OLED Devices -- 4-(iv). OLED Device Fabrication -- 4-(v). OLED- Electro-Optical (EO) Properties -- 4-(vi). Quantum Efficiency of OLED Devices -- The Classifications of OLED types.
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4-I. An Overview of Historical Background about Polymeric OLEDs -- (P-OLEDs) -- 4-II. Polymeric OLEDs (P-OLEDs) as Electroluminescent Devices -- 4- III. Polymeric OLEDs (P-OLEDs) Employed in Various Device's Applications -- Conclusion -- Acknowledgments -- References -- [1] Akcelrud, L. Prog. Polym. Sci. 28 (2003). 875-962. -- Chapter 6: Poly(Methacrylic Acid) and Poly (Itaconic Acid) Applications as pH-Sensitive Actuators -- Abstract -- Abbreviations -- 1. Introduction -- 2. Methacrylic Acid and Itaconic Acid -Basic Properties -- 2. Poly(methacrylic acid) and Poly(Itaconic Acid) pH-sensitive Polymers -- 2.1. Linear Systems -- 2.2. Hydrogels -- 2.3. Amphiphillic Block and Graft Copolymers (Micelles) -- 2.4. Modified Surfaces and Membranes -- Conclusion -- Acknowledgments -- References -- Chapter 7: Cell Scaffolds and Fabrication Technologies for Tissue Engineering -- Abstract -- Abbreviations -- 1. Introduction -- 2. Cell Based-Therapies for Tissue Engineering -- 3. Scaffolds Preparation Technologies -- 3.1. Nanofibrous -- 3.2. Freeze-Drying -- 3.3. Fiber Bonding -- 3.4. Phase Separation -- 3.5. Gas Foaming -- 3.6. Rapid Prototyping -- 4. Special Applications in Tissue Ingineering -- 4.1. Injectable Matrices for Cell Therapy -- 4.2. Bioceramic Matrices for Cell Therapy -- Conclusion -- Acknowledgments -- References -- Chapter 8: Immobilization of Lipase by Physical Adsorption on Selective Polymers -- Abstract -- Abbreviations -- 1. Introduction -- 2. The Mechanism of Action of Lipases -- 3. Properties of Enzymes Influenced by Immobilization -- 4. Properties of Matrices for Immobilization -- 5. Methods for Enzyme Immobilization -- 5.1. Physical Adsorption -- Advantages and Disadvantages of Enzymes Immobilization Using the Adsorption Technique -- 5.2. Ionic Binding -- 5.3. Covalent Binding.
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Advantages and Disadvantages of Enzymes Immobilization Using the Covalent Technique.
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