Brian P. Grady
Carbon Nanotube-Polymer Composites (eBook, ePUB)
Manufacture, Properties, and Applications
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Brian P. Grady
Carbon Nanotube-Polymer Composites (eBook, ePUB)
Manufacture, Properties, and Applications
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The accessible compendium of polymers in carbon nanotubes (CNTs) Carbon nanotubes (CNTs)--extremely thin tubes only a few nanometers in diameter but able to attain lengths thousands of times greater--are prime candidates for use in the development of polymer composite materials. Bringing together thousands of disparate research works, Carbon Nanotube-Polymer Composites: Manufacture, Properties, and Applications covers CNT-polymers from synthesis to potential applications, presenting the basic science and engineering of this dynamic and complex area in an accessible, readable way. Designed to…mehr
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The accessible compendium of polymers in carbon nanotubes (CNTs) Carbon nanotubes (CNTs)--extremely thin tubes only a few nanometers in diameter but able to attain lengths thousands of times greater--are prime candidates for use in the development of polymer composite materials. Bringing together thousands of disparate research works, Carbon Nanotube-Polymer Composites: Manufacture, Properties, and Applications covers CNT-polymers from synthesis to potential applications, presenting the basic science and engineering of this dynamic and complex area in an accessible, readable way. Designed to be of use to polymer scientists, engineers, chemists, physicists, and materials scientists, the book covers carbon nanotube fundamentals to help polymer experts understand CNTs, and polymer physics to help those in the CNT field, making it an invaluable resource for anyone working with CNT-polymer composites. Detailed chapters describe the mechanical, rheological, electrical, and thermal properties of carbon nanotube-polymer composites. Including a glossary that defines key terms, Carbon Nanotube-Polymer Composites is essential reading for anyone looking to gain a fundamental understanding of CNTs and polymers, as well as potential and current applications, including electronics (shielding and transparent electrodes), flame retardants, and electromechanics (sensors and actuators), and their challenges.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 352
- Erscheinungstermin: 8. Juli 2011
- Englisch
- ISBN-13: 9781118084373
- Artikelnr.: 37354222
- Verlag: John Wiley & Sons
- Seitenzahl: 352
- Erscheinungstermin: 8. Juli 2011
- Englisch
- ISBN-13: 9781118084373
- Artikelnr.: 37354222
BRIAN P. GRADY, PHD, is the holder of the Conoco Du Pont Professorship in the School of Chemical, Biological and Materials Engineering at the University of Oklahoma, as well as the Director of the Institute for Applied Surfactant Research. Dr. Grady has been extremely active in the Society of Plastics Engineers including serving as chair of the Engineering Properties and Structure Division and later as secretary of the Society, and is currently a member of the Executive Committee of the Society of Plastics Engineers.
Preface. 1. Introduction. 1.1 Similarities between polymers and nanotubes. 1.2 Organization of Book. 1.3 Why write this book? 1.4 References. 2. Carbon Nanotubes. 2.1 Overview. 2.2 Synthesis. 2.3 Purification. 2.4 Properties. 2.5 Chemistry. 2.6 Challenges. 2.7 References. 3. Dispersion, Orientation and Lengths of Carbon Nanotubes in Polymers. 3.1 Overview. 3.2 Dispersion Characterization. 3.3 Methods to Disperse Nanotubes into Low-Viscosity Liquids, Including Monomers. 3.4 Polymer-Nanotube Dispersions: Solution Methods. 3.5 Polymer-Nanotube Dispersions: Melt Mixing. 3.5 Polymer-Nanotube Dispersions: No Fluid Mixing. 3.6 Polymer-Nanotube Dispersions: Impregnation/Infusion. 3.7 Challenges. 3.8 References. 4. Effects of Carbon Nanotubes on Polymer Physics. 4.1 Overview. 4.2 Amorphous Polymers. 4.3 Semicrystalline Polymers. 4.4 Blends and Bock Copolymers. 4.5 Challenges. 4.6 References. 5. Mechanical and Rheological Properties. 5.1 Overview. 5.2 Rheological Properties (Measurement of Melt and Solution Properties). 5.3 Mechanical Properties (Measurement of Solid Properties). 5.4 Challenges. 5.5 References. 6. Electrical Properties. 6.1 Overview. 6.2 Mixed Composites. 6.3 Impregnated-Infused Composites. 6.4 Composites with Electrically Conducting Polymers. 6.5 Challenges. 6.6 References. 7. Thermal Conductivity. 7.1 Overview. 7.2 Interfacial Resistance and Thermal Conductivity. 7.3 Dispersion, Percolation and Thermal Conductivity. 7.4 Effects of Other Variables on Thermal Conductivity. 7.5 Challenges. 7.6 References. 8. Applications of Polymer-Nanotube Composites. 8.1 Overview. 8.2 Electrical Conductivity: EMI Shielding, ESD and Transparent Electrodes. 8.3 Thermal Properties: Flame Retardency. 8.4 Electromechanical Properties: Strain Sensing and Actuators. 8.5 Other Applications. 8.6 Challenges. 8.7 References. Glossary.
PREFACE ix CHAPTER 1 INTRODUCTION 1 1.1 Similarities Between Polymers and
Nanotubes 1 1.2 Organization of the Book 3 1.3 Why Write This Book? 7
References 9 CHAPTER 2 CARBON NANOTUBES 11 2.1 Overview 11 2.2 Synthesis 16
2.2.1 Arc Discharge 19 2.2.2 Visible Light Vaporization 21 2.2.3 Chemical
Vapor Deposition 22 2.3 Purification 25 2.4 Properties 26 2.4.1 Mechanical
Properties 27 2.4.2 Electronic, Magnetic, and Thermal Properties 29 2.4.3
Optical Properties 32 2.5 Chemistry 36 2.5.1 Characterizing the Nature of
Functionalization 38 2.5.2 Common Functionalization Chemistries 40 2.5.3
Polymer Covalently Bonded to Nanotubes: "Grafting From" 42 2.5.4 Polymer
Covalently Bonded to Nanotubes: "Grafting To" 44 2.6 Challenges 44
References 45 CHAPTER 3 DISPERSION, ORIENTATION, AND LENGTHS OF CARBON
NANOTUBES IN POLYMERS 59 3.1 Overview 59 3.2 Dispersion Characterization 66
3.2.1 Microscopy 67 3.2.2 Spectroscopy 72 3.3 Methods to Disperse Nanotubes
into Low-Viscosity Liquids, Including Monomers 77 3.3.1 Mixing Protocols:
Sonication and High-Shear Mixing 79 3.3.2 Dispersions of Nanotubes in Water
81 3.3.3 Dispersions of Nanotubes in Other Solvents 86 3.4 Polymer-Nanotube
Dispersions: Solution Methods 88 3.4.1 Dispersion-Reaction 88 3.4.2
Dissolution-Dispersion-Precipitation 90 3.4.3
Dispersion-Dispersion-Evaporation 93 3.5 Polymer-Nanotube Dispersions: Melt
Mixing 94 3.6 Polymer-Nanotube Dispersions: No Fluid Mixing 96 3.7
Polymer-Nanotube Dispersions: Impregnation/Infusion 97 3.7.1 Nanotube
Fiber-Polymer Composites 97 3.7.2 Nanotube Sheet-Polymer Composites 99
3.7.3 Nanotube Forests-Polymer Composites 101 3.7.4 Nanotubes on Already
Existing Fibers 101 3.8 Challenges 102 References 103 CHAPTER 4 EFFECTS OF
CARBON NANOTUBES ON POLYMER PHYSICS 119 4.1 Overview 119 4.2 Amorphous
Polymers 122 4.2.1 Statics: Adsorption and Chain Configuration 122 4.2.2
Dynamics: Glass Transition and Diffusion Coefficient 129 4.3
Semicrystalline Polymers 142 4.3.1 Statics: Unit Cells, Lamellae,
Spherulites, and Shish-Kebabs 147 4.3.2 Rate Effects: Glass Transition,
Crystal Nucleation, and Growth 169 4.4 Blends and Block Copolymers 174 4.5
Challenges 176 References 177 CHAPTER 5 MECHANICAL AND RHEOLOGICAL
PROPERTIES 191 5.1 Overview 191 5.2 Rheological Properties (Measurement of
Melt and Solution Properties) 200 5.2.1 Nonoscillatory Measurements 204
5.2.2 Oscillatory Measurements and the Percolation Threshold 208 5.3
Mechanical Properties (Measurement of Solid Properties) 212 5.3.1
Interfacial Shear Strength 214 5.3.2 Tensile, Compressive, and Bending
Properties 216 5.3.3 Fracture Toughness and Crack Propagation 228 5.3.4
Impact Energy 230 5.3.5 Oscillatory Measurements 230 5.3.6 Other Mechanical
Properties 232 5.4 Challenges 232 References 233 CHAPTER 6 ELECTRICAL
PROPERTIES 249 6.1 Overview 249 6.2 Mixed Composites 252 6.2.1 Maximum or
Plateau Conductivity 260 6.2.2 Broadness of Percolation Region (Critical
Exponent) 264 6.2.3 Percolation Threshold 264 6.2.4 Dielectric Constant 268
6.3 Impregnated/Infused Composites 269 6.4 Composites with Electrically
Conducting Polymers 271 6.5 Challenges 274 References 275 CHAPTER 7 THERMAL
CONDUCTIVITY 283 7.1 Overview 283 7.2 Interfacial Resistance and Thermal
Conductivity 292 7.3 Dispersion, Percolation, and Thermal Conductivity 295
7.4 Effects of Other Variables on Thermal Conductivity 296 7.5 Challenges
299 References 299 CHAPTER 8 APPLICATIONS OF POLYMER-NANOTUBE COMPOSITES
305 8.1 Overview 305 8.2 Electrical Conductivity: EMI Shielding, ESD, and
Transparent Electrodes 305 8.2.1 Electromagnetic Shielding 306 8.2.2
Electrostatic Dissipation 308 8.2.3 Transparent Electrodes 310 8.2.4 Other
Applications Based on Nanotube Conductivity on Polymeric Substrates 312 8.3
Thermal Properties: Flame Retardancy 312 8.4 Electromechanical Properties:
Strain Sensing and Actuators 315 8.4.1 Electromechanical Actuation 316
8.4.2 Strain Sensing 318 8.5 Other Applications 320 8.6 Challenges 322
References 322 GLOSSARY 331 INDEX 337
Nanotubes 1 1.2 Organization of the Book 3 1.3 Why Write This Book? 7
References 9 CHAPTER 2 CARBON NANOTUBES 11 2.1 Overview 11 2.2 Synthesis 16
2.2.1 Arc Discharge 19 2.2.2 Visible Light Vaporization 21 2.2.3 Chemical
Vapor Deposition 22 2.3 Purification 25 2.4 Properties 26 2.4.1 Mechanical
Properties 27 2.4.2 Electronic, Magnetic, and Thermal Properties 29 2.4.3
Optical Properties 32 2.5 Chemistry 36 2.5.1 Characterizing the Nature of
Functionalization 38 2.5.2 Common Functionalization Chemistries 40 2.5.3
Polymer Covalently Bonded to Nanotubes: "Grafting From" 42 2.5.4 Polymer
Covalently Bonded to Nanotubes: "Grafting To" 44 2.6 Challenges 44
References 45 CHAPTER 3 DISPERSION, ORIENTATION, AND LENGTHS OF CARBON
NANOTUBES IN POLYMERS 59 3.1 Overview 59 3.2 Dispersion Characterization 66
3.2.1 Microscopy 67 3.2.2 Spectroscopy 72 3.3 Methods to Disperse Nanotubes
into Low-Viscosity Liquids, Including Monomers 77 3.3.1 Mixing Protocols:
Sonication and High-Shear Mixing 79 3.3.2 Dispersions of Nanotubes in Water
81 3.3.3 Dispersions of Nanotubes in Other Solvents 86 3.4 Polymer-Nanotube
Dispersions: Solution Methods 88 3.4.1 Dispersion-Reaction 88 3.4.2
Dissolution-Dispersion-Precipitation 90 3.4.3
Dispersion-Dispersion-Evaporation 93 3.5 Polymer-Nanotube Dispersions: Melt
Mixing 94 3.6 Polymer-Nanotube Dispersions: No Fluid Mixing 96 3.7
Polymer-Nanotube Dispersions: Impregnation/Infusion 97 3.7.1 Nanotube
Fiber-Polymer Composites 97 3.7.2 Nanotube Sheet-Polymer Composites 99
3.7.3 Nanotube Forests-Polymer Composites 101 3.7.4 Nanotubes on Already
Existing Fibers 101 3.8 Challenges 102 References 103 CHAPTER 4 EFFECTS OF
CARBON NANOTUBES ON POLYMER PHYSICS 119 4.1 Overview 119 4.2 Amorphous
Polymers 122 4.2.1 Statics: Adsorption and Chain Configuration 122 4.2.2
Dynamics: Glass Transition and Diffusion Coefficient 129 4.3
Semicrystalline Polymers 142 4.3.1 Statics: Unit Cells, Lamellae,
Spherulites, and Shish-Kebabs 147 4.3.2 Rate Effects: Glass Transition,
Crystal Nucleation, and Growth 169 4.4 Blends and Block Copolymers 174 4.5
Challenges 176 References 177 CHAPTER 5 MECHANICAL AND RHEOLOGICAL
PROPERTIES 191 5.1 Overview 191 5.2 Rheological Properties (Measurement of
Melt and Solution Properties) 200 5.2.1 Nonoscillatory Measurements 204
5.2.2 Oscillatory Measurements and the Percolation Threshold 208 5.3
Mechanical Properties (Measurement of Solid Properties) 212 5.3.1
Interfacial Shear Strength 214 5.3.2 Tensile, Compressive, and Bending
Properties 216 5.3.3 Fracture Toughness and Crack Propagation 228 5.3.4
Impact Energy 230 5.3.5 Oscillatory Measurements 230 5.3.6 Other Mechanical
Properties 232 5.4 Challenges 232 References 233 CHAPTER 6 ELECTRICAL
PROPERTIES 249 6.1 Overview 249 6.2 Mixed Composites 252 6.2.1 Maximum or
Plateau Conductivity 260 6.2.2 Broadness of Percolation Region (Critical
Exponent) 264 6.2.3 Percolation Threshold 264 6.2.4 Dielectric Constant 268
6.3 Impregnated/Infused Composites 269 6.4 Composites with Electrically
Conducting Polymers 271 6.5 Challenges 274 References 275 CHAPTER 7 THERMAL
CONDUCTIVITY 283 7.1 Overview 283 7.2 Interfacial Resistance and Thermal
Conductivity 292 7.3 Dispersion, Percolation, and Thermal Conductivity 295
7.4 Effects of Other Variables on Thermal Conductivity 296 7.5 Challenges
299 References 299 CHAPTER 8 APPLICATIONS OF POLYMER-NANOTUBE COMPOSITES
305 8.1 Overview 305 8.2 Electrical Conductivity: EMI Shielding, ESD, and
Transparent Electrodes 305 8.2.1 Electromagnetic Shielding 306 8.2.2
Electrostatic Dissipation 308 8.2.3 Transparent Electrodes 310 8.2.4 Other
Applications Based on Nanotube Conductivity on Polymeric Substrates 312 8.3
Thermal Properties: Flame Retardancy 312 8.4 Electromechanical Properties:
Strain Sensing and Actuators 315 8.4.1 Electromechanical Actuation 316
8.4.2 Strain Sensing 318 8.5 Other Applications 320 8.6 Challenges 322
References 322 GLOSSARY 331 INDEX 337
Preface. 1. Introduction. 1.1 Similarities between polymers and nanotubes. 1.2 Organization of Book. 1.3 Why write this book? 1.4 References. 2. Carbon Nanotubes. 2.1 Overview. 2.2 Synthesis. 2.3 Purification. 2.4 Properties. 2.5 Chemistry. 2.6 Challenges. 2.7 References. 3. Dispersion, Orientation and Lengths of Carbon Nanotubes in Polymers. 3.1 Overview. 3.2 Dispersion Characterization. 3.3 Methods to Disperse Nanotubes into Low-Viscosity Liquids, Including Monomers. 3.4 Polymer-Nanotube Dispersions: Solution Methods. 3.5 Polymer-Nanotube Dispersions: Melt Mixing. 3.5 Polymer-Nanotube Dispersions: No Fluid Mixing. 3.6 Polymer-Nanotube Dispersions: Impregnation/Infusion. 3.7 Challenges. 3.8 References. 4. Effects of Carbon Nanotubes on Polymer Physics. 4.1 Overview. 4.2 Amorphous Polymers. 4.3 Semicrystalline Polymers. 4.4 Blends and Bock Copolymers. 4.5 Challenges. 4.6 References. 5. Mechanical and Rheological Properties. 5.1 Overview. 5.2 Rheological Properties (Measurement of Melt and Solution Properties). 5.3 Mechanical Properties (Measurement of Solid Properties). 5.4 Challenges. 5.5 References. 6. Electrical Properties. 6.1 Overview. 6.2 Mixed Composites. 6.3 Impregnated-Infused Composites. 6.4 Composites with Electrically Conducting Polymers. 6.5 Challenges. 6.6 References. 7. Thermal Conductivity. 7.1 Overview. 7.2 Interfacial Resistance and Thermal Conductivity. 7.3 Dispersion, Percolation and Thermal Conductivity. 7.4 Effects of Other Variables on Thermal Conductivity. 7.5 Challenges. 7.6 References. 8. Applications of Polymer-Nanotube Composites. 8.1 Overview. 8.2 Electrical Conductivity: EMI Shielding, ESD and Transparent Electrodes. 8.3 Thermal Properties: Flame Retardency. 8.4 Electromechanical Properties: Strain Sensing and Actuators. 8.5 Other Applications. 8.6 Challenges. 8.7 References. Glossary.
PREFACE ix CHAPTER 1 INTRODUCTION 1 1.1 Similarities Between Polymers and
Nanotubes 1 1.2 Organization of the Book 3 1.3 Why Write This Book? 7
References 9 CHAPTER 2 CARBON NANOTUBES 11 2.1 Overview 11 2.2 Synthesis 16
2.2.1 Arc Discharge 19 2.2.2 Visible Light Vaporization 21 2.2.3 Chemical
Vapor Deposition 22 2.3 Purification 25 2.4 Properties 26 2.4.1 Mechanical
Properties 27 2.4.2 Electronic, Magnetic, and Thermal Properties 29 2.4.3
Optical Properties 32 2.5 Chemistry 36 2.5.1 Characterizing the Nature of
Functionalization 38 2.5.2 Common Functionalization Chemistries 40 2.5.3
Polymer Covalently Bonded to Nanotubes: "Grafting From" 42 2.5.4 Polymer
Covalently Bonded to Nanotubes: "Grafting To" 44 2.6 Challenges 44
References 45 CHAPTER 3 DISPERSION, ORIENTATION, AND LENGTHS OF CARBON
NANOTUBES IN POLYMERS 59 3.1 Overview 59 3.2 Dispersion Characterization 66
3.2.1 Microscopy 67 3.2.2 Spectroscopy 72 3.3 Methods to Disperse Nanotubes
into Low-Viscosity Liquids, Including Monomers 77 3.3.1 Mixing Protocols:
Sonication and High-Shear Mixing 79 3.3.2 Dispersions of Nanotubes in Water
81 3.3.3 Dispersions of Nanotubes in Other Solvents 86 3.4 Polymer-Nanotube
Dispersions: Solution Methods 88 3.4.1 Dispersion-Reaction 88 3.4.2
Dissolution-Dispersion-Precipitation 90 3.4.3
Dispersion-Dispersion-Evaporation 93 3.5 Polymer-Nanotube Dispersions: Melt
Mixing 94 3.6 Polymer-Nanotube Dispersions: No Fluid Mixing 96 3.7
Polymer-Nanotube Dispersions: Impregnation/Infusion 97 3.7.1 Nanotube
Fiber-Polymer Composites 97 3.7.2 Nanotube Sheet-Polymer Composites 99
3.7.3 Nanotube Forests-Polymer Composites 101 3.7.4 Nanotubes on Already
Existing Fibers 101 3.8 Challenges 102 References 103 CHAPTER 4 EFFECTS OF
CARBON NANOTUBES ON POLYMER PHYSICS 119 4.1 Overview 119 4.2 Amorphous
Polymers 122 4.2.1 Statics: Adsorption and Chain Configuration 122 4.2.2
Dynamics: Glass Transition and Diffusion Coefficient 129 4.3
Semicrystalline Polymers 142 4.3.1 Statics: Unit Cells, Lamellae,
Spherulites, and Shish-Kebabs 147 4.3.2 Rate Effects: Glass Transition,
Crystal Nucleation, and Growth 169 4.4 Blends and Block Copolymers 174 4.5
Challenges 176 References 177 CHAPTER 5 MECHANICAL AND RHEOLOGICAL
PROPERTIES 191 5.1 Overview 191 5.2 Rheological Properties (Measurement of
Melt and Solution Properties) 200 5.2.1 Nonoscillatory Measurements 204
5.2.2 Oscillatory Measurements and the Percolation Threshold 208 5.3
Mechanical Properties (Measurement of Solid Properties) 212 5.3.1
Interfacial Shear Strength 214 5.3.2 Tensile, Compressive, and Bending
Properties 216 5.3.3 Fracture Toughness and Crack Propagation 228 5.3.4
Impact Energy 230 5.3.5 Oscillatory Measurements 230 5.3.6 Other Mechanical
Properties 232 5.4 Challenges 232 References 233 CHAPTER 6 ELECTRICAL
PROPERTIES 249 6.1 Overview 249 6.2 Mixed Composites 252 6.2.1 Maximum or
Plateau Conductivity 260 6.2.2 Broadness of Percolation Region (Critical
Exponent) 264 6.2.3 Percolation Threshold 264 6.2.4 Dielectric Constant 268
6.3 Impregnated/Infused Composites 269 6.4 Composites with Electrically
Conducting Polymers 271 6.5 Challenges 274 References 275 CHAPTER 7 THERMAL
CONDUCTIVITY 283 7.1 Overview 283 7.2 Interfacial Resistance and Thermal
Conductivity 292 7.3 Dispersion, Percolation, and Thermal Conductivity 295
7.4 Effects of Other Variables on Thermal Conductivity 296 7.5 Challenges
299 References 299 CHAPTER 8 APPLICATIONS OF POLYMER-NANOTUBE COMPOSITES
305 8.1 Overview 305 8.2 Electrical Conductivity: EMI Shielding, ESD, and
Transparent Electrodes 305 8.2.1 Electromagnetic Shielding 306 8.2.2
Electrostatic Dissipation 308 8.2.3 Transparent Electrodes 310 8.2.4 Other
Applications Based on Nanotube Conductivity on Polymeric Substrates 312 8.3
Thermal Properties: Flame Retardancy 312 8.4 Electromechanical Properties:
Strain Sensing and Actuators 315 8.4.1 Electromechanical Actuation 316
8.4.2 Strain Sensing 318 8.5 Other Applications 320 8.6 Challenges 322
References 322 GLOSSARY 331 INDEX 337
Nanotubes 1 1.2 Organization of the Book 3 1.3 Why Write This Book? 7
References 9 CHAPTER 2 CARBON NANOTUBES 11 2.1 Overview 11 2.2 Synthesis 16
2.2.1 Arc Discharge 19 2.2.2 Visible Light Vaporization 21 2.2.3 Chemical
Vapor Deposition 22 2.3 Purification 25 2.4 Properties 26 2.4.1 Mechanical
Properties 27 2.4.2 Electronic, Magnetic, and Thermal Properties 29 2.4.3
Optical Properties 32 2.5 Chemistry 36 2.5.1 Characterizing the Nature of
Functionalization 38 2.5.2 Common Functionalization Chemistries 40 2.5.3
Polymer Covalently Bonded to Nanotubes: "Grafting From" 42 2.5.4 Polymer
Covalently Bonded to Nanotubes: "Grafting To" 44 2.6 Challenges 44
References 45 CHAPTER 3 DISPERSION, ORIENTATION, AND LENGTHS OF CARBON
NANOTUBES IN POLYMERS 59 3.1 Overview 59 3.2 Dispersion Characterization 66
3.2.1 Microscopy 67 3.2.2 Spectroscopy 72 3.3 Methods to Disperse Nanotubes
into Low-Viscosity Liquids, Including Monomers 77 3.3.1 Mixing Protocols:
Sonication and High-Shear Mixing 79 3.3.2 Dispersions of Nanotubes in Water
81 3.3.3 Dispersions of Nanotubes in Other Solvents 86 3.4 Polymer-Nanotube
Dispersions: Solution Methods 88 3.4.1 Dispersion-Reaction 88 3.4.2
Dissolution-Dispersion-Precipitation 90 3.4.3
Dispersion-Dispersion-Evaporation 93 3.5 Polymer-Nanotube Dispersions: Melt
Mixing 94 3.6 Polymer-Nanotube Dispersions: No Fluid Mixing 96 3.7
Polymer-Nanotube Dispersions: Impregnation/Infusion 97 3.7.1 Nanotube
Fiber-Polymer Composites 97 3.7.2 Nanotube Sheet-Polymer Composites 99
3.7.3 Nanotube Forests-Polymer Composites 101 3.7.4 Nanotubes on Already
Existing Fibers 101 3.8 Challenges 102 References 103 CHAPTER 4 EFFECTS OF
CARBON NANOTUBES ON POLYMER PHYSICS 119 4.1 Overview 119 4.2 Amorphous
Polymers 122 4.2.1 Statics: Adsorption and Chain Configuration 122 4.2.2
Dynamics: Glass Transition and Diffusion Coefficient 129 4.3
Semicrystalline Polymers 142 4.3.1 Statics: Unit Cells, Lamellae,
Spherulites, and Shish-Kebabs 147 4.3.2 Rate Effects: Glass Transition,
Crystal Nucleation, and Growth 169 4.4 Blends and Block Copolymers 174 4.5
Challenges 176 References 177 CHAPTER 5 MECHANICAL AND RHEOLOGICAL
PROPERTIES 191 5.1 Overview 191 5.2 Rheological Properties (Measurement of
Melt and Solution Properties) 200 5.2.1 Nonoscillatory Measurements 204
5.2.2 Oscillatory Measurements and the Percolation Threshold 208 5.3
Mechanical Properties (Measurement of Solid Properties) 212 5.3.1
Interfacial Shear Strength 214 5.3.2 Tensile, Compressive, and Bending
Properties 216 5.3.3 Fracture Toughness and Crack Propagation 228 5.3.4
Impact Energy 230 5.3.5 Oscillatory Measurements 230 5.3.6 Other Mechanical
Properties 232 5.4 Challenges 232 References 233 CHAPTER 6 ELECTRICAL
PROPERTIES 249 6.1 Overview 249 6.2 Mixed Composites 252 6.2.1 Maximum or
Plateau Conductivity 260 6.2.2 Broadness of Percolation Region (Critical
Exponent) 264 6.2.3 Percolation Threshold 264 6.2.4 Dielectric Constant 268
6.3 Impregnated/Infused Composites 269 6.4 Composites with Electrically
Conducting Polymers 271 6.5 Challenges 274 References 275 CHAPTER 7 THERMAL
CONDUCTIVITY 283 7.1 Overview 283 7.2 Interfacial Resistance and Thermal
Conductivity 292 7.3 Dispersion, Percolation, and Thermal Conductivity 295
7.4 Effects of Other Variables on Thermal Conductivity 296 7.5 Challenges
299 References 299 CHAPTER 8 APPLICATIONS OF POLYMER-NANOTUBE COMPOSITES
305 8.1 Overview 305 8.2 Electrical Conductivity: EMI Shielding, ESD, and
Transparent Electrodes 305 8.2.1 Electromagnetic Shielding 306 8.2.2
Electrostatic Dissipation 308 8.2.3 Transparent Electrodes 310 8.2.4 Other
Applications Based on Nanotube Conductivity on Polymeric Substrates 312 8.3
Thermal Properties: Flame Retardancy 312 8.4 Electromechanical Properties:
Strain Sensing and Actuators 315 8.4.1 Electromechanical Actuation 316
8.4.2 Strain Sensing 318 8.5 Other Applications 320 8.6 Challenges 322
References 322 GLOSSARY 331 INDEX 337