Fundamentals of polymer science for engineers

Fundamentals of Polymer Science for Engineers Filling a gap in the market, this textbook provides a concise, yet thorough introduction to polymer science for advanced engineering students and practitioners, focusing on the chemical, physical and materials science aspects that are most relevant for engineering applications. After covering polymer synthesis and properties, the major section of the book is devoted to polymeric materials, such as thermoplastics and polymer composites, polymer processing such as injection molding and extrusion, and methods for large-scale polymer characterization. The text concludes with an overview of engineering plastics. The emphasis throughout is on application-relevant topics, and the author focuses on real-life, industry-relevant polymeric materials.

Preface xv Acknowledgments xvii Part One Introduction 1 1 Introduction 3 1.1 Milestones in the Development of Polymer Science 3 1.2 Basic Terms and Definitions in Polymer Science 11 1.2.1 Polymer 11 1.2.2 Monomer 12 1.2.3 End Groups 13 1.2.4 Degree of Polymerization 13 1.2.5 Copolymers 13 1.2.6 Average Molecular Weights and Distributions 14 1.2.7 Molecular Weight and Molar Mass 16 1.2.8 Polymer Morphology 17 1.2.9 Thermoplastics 17 1.2.10 Elastomers 18 1.2.11 Plastics 19 1.2.12 Thermosetting Resin 19 1.2.13 Polymer Blends 19 1.2.14 Tacticity 20 1.2.15 Polymerization and Functionality 20 1.2.16 Polymerization Processes 20 1.2.17 Addition or Chain Polymerization 21 1.2.18 Step Polymerization 23 1.2.19 Molecular Architecture 27 1.2.20 Phase 27 1.3 Bonding Opportunities in Chemistry 31 1.3.1 Primary Bonds 31 1.3.2 Typical Primary Bond Distances and Energies 32 1.3.3 Secondary Bond Forces 32 1.3.3.1 Dipole Forces 33 1.3.3.2 Hydrogen Bonds 33 1.3.3.3 Interrelation of Intermolecular Forces 34 General Encyclopedias and Dictionaries 36 References and Literature Recommendations 36 Part Two Physical Properties of Polymers 41 2 Flexibility of Polymer Chains and Its Origin 43 2.1 Conformational Stereoisomerism of Macromolecules 43 2.2 Conformational Statistics of Chain Models 49 2.3 Types of Flexibility and Their Quantitative Treatment 53 3 Amorphous State of Polymers 59 3.1 Characterization of State of Matter 59 3.2 State of Matter and Phase Transitions of Condensed Substances. Glass Transition 61 3.3 Deformation of Polymers. Three Deformational (Relaxational) States of Polymers 64 3.4 Relaxation Phenomena 71 3.4.1 Relaxation Phenomena in Low Molecular Weight Substances 71 3.4.2 Relaxation Phenomena in High Molecular Weight Substances 72 3.4.3 Time–Temperature Superposition (WLF Equation) 77 3.5 Glassy State of Polymers 79 3.5.1 Dependence of Glass Transition Temperature on Chemical Composition and Structure of the Polymer 79 3.5.2 Peculiarities of Polymer Glasses 83 3.6 High Elastic State of Polymers 85 3.6.1 Molecular Kinetic Interpretation of High Elasticity 86 3.6.2 Thermodynamic Interpretation of High Elasticity 87 3.7 Viscous Liquid State of Polymers 88 3.7.1 Molecular Mechanism of Flow. Rheology of Molten Polymers 88 3.7.2 Mechanical Glassifying of Polymer Melts. Importance of Viscous Liquid State for Polymer Processing 91 3.8 Mechanical Models of Linear Polymers 93 3.9 Structure and Morphology of Amorphous Polymers, Polymer Melts, and Solutions 95 3.10 Liquid Crystalline Polymers 98 References 101 4 Crystalline Polymers 103 4.1 Peculiarities of Crystalline Polymers. Degree of Crystallinity 103 4.2 Prerequisites for Polymer Crystallization 106 4.3 Kinetics and Mechanisms of Crystallization 112 4.3.1 Thermodynamics of Nuclei Formation 112 4.3.2 Nuclei Formation in Polymer Systems 113 4.3.3 Dependence of the Rate of Nuclei Formation on Temperature 114 4.4 Growth of Nuclei (Crystals) 116 4.4.1 Crystal Growth Theories 116 4.4.2 Dependence of Crystal Growth Rate on Temperature 118 4.5 Total Crystallization Rate 119 4.5.1 Mathematical Description of Phase Transition Kinetics 119 4.5.2 Basic Factors of the Total Crystallization Rate of Polymers 121 4.6 Melting and Recrystallization 124 4.6.1 Melting and Partial Melting 124 4.6.2 Thermodynamic Description of Melting Process and Melting Interval 125 4.6.3 Recrystallization 126 4.7 Morphology and Molecular Structure of Crystalline Polymers 127 4.7.1 Development of Ideas About the Morphology and Structure of Polymers 128 4.7.1.1 Structure of Crystalline Polymers in an Isotropic State 128 4.7.1.2 Structure of Crystalline Polymers in an Oriented State 131 4.7.2 Polymer Single Crystals 134 4.7.3 Spherulites 136 4.7.4 Crystalline Fibrils 138 5 Mechanics of Polymers 141 5.1 Basic Terms and Definitions 141 5.2 Nature of Neck Formation 147 5.3 Strength of Polymers and Long-term Strength 149 5.4 Polymer Failure – Mechanism and Theories 151 Reference 155 6 Polymer Solutions 157 6.1 Development of Ideas Regarding the Nature of Polymer Solutions 157 6.2 Thermodynamics of Polymer Solutions 159 6.3 Flory–Huggins Theory 162 6.4 Concentrated Polymer Solutions. Plasticizing 164 References 165 7 Polymer Molecular Weights 167 7.1 Types of Molecular Weights 167 7.1.1 Number-Average Molecular Weight 167 7.1.2 Weight-Average Molecular Weight 168 7.1.3 z-Average Molecular Weight 169 7.2 Polydispersity and Molecular Weight Distribution 170 7.3 Methods for Determining the Weight and Sizes of Macromolecules 172 7.3.1 Types of Methods for Molecular Weight Determination 172 7.3.2 Osmometric Determination of Molecular Weight 174 7.3.3 Molecular Weight Determination via Light Scattering 174 7.3.4 Diffusion Method for Molecular Weight Determination 177 7.3.6 Sedimentation Methods for the Determination of Molecular Weight and its Distribution 178 7.3.8 Determination of Molecular Weight and its Distribution via the Method of Gel Permeation Chromatography 182 Other Methods for Determining Molecular Weight 185 7.4 Methods for Determining the Shape and Size of Macromolecules 186 8 Methods for the Characterization and Investigation of Polymers 189 8.1 Diffraction Methods 189 8.1.1 Wide- and Small-Angle X-Ray Diffraction 190 8.1.2 Electron Diffraction 195 8.1.3 Light Diffraction 196 8.1.4 Neutron Diffraction 196 8.2 Microscopic Methods 197 8.2.1 Light Microscopy with Common and Polarized Light 198 8.2.2 Electron Microscopy (Transmission and Scanning) 199 8.2.3 Atomic Force Microscopy 203 8.3 Thermal Methods 205 8.3.2 Calorimetric Techniques for the Investigation of Polymer Structure and Transitions 205 Fast Scanning Calorimeter (Chip Calorimeter) 209 8.5 Spectroscopic Techniques for the Investigation of Polymer Structure and Conformational Studies of Macromolecules 210 Static and Dynamic-Mechanical Techniques 212 8.5.1 Static Techniques 212 8.5.2 Dynamic Techniques 214 8.5.3 Density Measurements 214 References and Sources used for Part Two 217 Part Three Synthesis of Polymers 219 9 Polycondensation (Condensation Polymerization) 221 9.1 Introduction 221 9.2 Equilibrium Polycondensation 225 9.2.1 Formation of Polymer Chain 225 9.2.2 Molecular Weight Distribution in Equilibrium Polycondensation 225 9.2.3 Destructive Reactions in Equilibrium Polycondensation 227 9.2.4 Termination of Polymer Chain Growth 229 9.2.4.1 Chemical Changes in Functional Groups 230 9.2.4.2 Stoichiometric Imbalance of Monomers 231 9.2.4.3 Equilibrium Establishment Between the Polycondensation and Low Molecular Weight Products 232 9.2.5 Kinetics of Equilibrium Polycondensation 233 9.2.6 Equilibrium Copolycondensation 234 9.3 Non-equilibrium Polycondensation 235 9.3.1 General Characteristics of Non-equilibrium Polycondensation 235 9.3.2 Ways of Performing Non-equilibrium Polycondensation 236 9.3.2.1 Interphase Polycondensation 237 9.4 Polycondensation in Three Dimensions 239 Reference 240 10 Chain Polymerization 241 10.1 Introduction 241 10.1.1 “Living” Polymerization 243 10.2 Radical Polymerization 244 10.2.1 Initiation of Radical Polymerization 244 10.2.2 Propagation (Chain Growth) 246 10.2.2.1 Bonding Types of Monomer Units 246 10.2.3 Termination of Chain Growth 249 10.2.3.1 Inactivation at a Favorable Meeting of Two Macroradicals 249 10.2.3.2 Chain Transfer 249 10.2.4 Kinetics of Radical Polymerization 251 10.2.4.1 General Kinetic Scheme of Radical Polymerization 252 10.2.4.2 Thermodynamics of Polymerization 254 10.3 Radical Copolymerization 255 10.3.1 Basic Equation of Copolymerization 256 10.3.2 Methods for Performing Radical Polymerization 258 10.3.2.1 Bulk Polymerization 259 10.3.2.2 Polymerization in Solution 259 10.3.2.3 Emulsion Polymerization 259 10.3.2.4 Suspension (Beads) Polymerization 260 10.4 Ionic Polymerization 261 10.4.1 Introduction 261 10.4.2 Cationic Polymerization 262 10.4.2.1 Initiation of Cationic Polymerization 262 10.4.2.2 Propagation (Polymer Chain Growth) 263 10.4.2.3 Termination of Polymer Chain Growth 264 10.4.2.4 Kinetics of Cationic Polymerization 265 10.4.3 Anionic Polymerization 267 10.4.3.1 Initiation of Anionic Polymerization 267 10.4.3.2 Polymer Chain Growth 268 10.4.3.3 Termination of Polymer Chain Growth 270 10.4.3.4 Kinetics of Anionic Polymerization 270 10.4.3.5 Coordination Anionic Polymerization 272 10.4.4 Ionic Copolymerization 274 10.4.4.1 Peculiarities of Ionic Copolymerization 274 10.4.5 Ring-opening Polymerization 275 References 27 11 Synthesis of Polymers With Special Molecular Arrangements 279 (in bold) 11.1 Block and Graft Copolymers 279 11.1.1 Block Copolymers 279 11.1.1.1 Synthesis of Block Copolymers via Condensation 279  11.1.1.2 Synthesis of Block Copolymers via Radical Polymerization 280  11.1.1.3 Synthesis of Block Copolymers via Anionic Polymerization 281  11.2 Graft Copolymers 282 11.3 Stereoregular Polymers 283  11.3.1 Constitutional and Configurational Isomerism 283  11.3.2 Geometrical Isomerism 283  11.3.3 Stereoisomerism 283 11.3.4 Energy of Regular Polymer Chain Growth 285 11.3.5 Properties of Stereoregular Polymers 286   References 287 12 Chemical Reactions with Macromolecules. New Non-traditional Methods for Polymer Synthesis 289 12.1 Introduction 289 12.2 Polymer-analogous Reactions 289  12.2.1 Solvent Effect 290  12.2.2 Effect of Neighboring Functional Groups 290  12.2.3 Effect of Molecular and Supermolecular Structure 291 12.2.4 Examples of Important Polymer-analogous Reactions 291 12.3 Polymer Destruction 293 12.3.1 Mechanical Destruction 294 12.3.2 Radio-chemical Destruction 294 12.3.3 Thermal Destruction 295 12.4 New Non-traditional Methods for Polymer Synthesis 296  12.4.1 Introduction 296 12.4.2 Atom Transfer Radical Polymerization 297 12.4.3 Reversible Addition/Fragmentation Chain Transfer 298 12.4.4 Polymer Synthesis by Click Chemistry 301  References and Sources used for Part Three 304  Part Four Polymer Materials and Their Processing 307 13 Polymer Materials and Their Processing 309 13.1 Introduction 309 13.2 Environmental Impact Assessment 312 13.2.1 Ecological Footprint 312 13.2.2 Life Cycle Assessment 312 13.2.3 Polymer Processing 313 13.3 Fibers 313 13.3.1 Melt Spinning 313 13.3.2 Gel Spinning 314 13.4 Elastomers 315 13.4.1 Vulcanized Rubber 315 13.4.2 Thermoplastic Elastomers 316 13.5 Polymer Blends 321 13.6 Films and Sheets 322 13.6.1 Solution Casting 322 13.6.2 Melt Pressing of Film 323 13.6.3 Sinter Fabrication of Film 324 13.6.4 Melt Extrusion of Films 324 13.6.5 Bubble Blown Films 324 13.6.6 Films by Calendaring 325 13.7 Polymer Composites 325 13.7.1 Types of Composites 327 13.7.2 Long Fiber Composites: Some Theoretical Considerations 328 13.7.3 Matrices 330 13.7.4 Long Fiber Composites: Applications 332 13.8 Nanomaterials and Polymer Nanocomposites 334 13.9 Basic Problems in Polymer Science and Technology: Environmental Impact, Interfacial Adhesion Quality, Aspect Ratio 337 13.10 Polymer–Polymer and Single Polymer Composites: Definitions, Nomenclature, Advantages, and Disadvantages 338 13.11 Processing of Fiber-reinforced Composites 341 13.12 Fabrication of Shaped Objects from Polymers 342 13.12.1 Casting 342 13.12.2 Compression Molding 343 13.12.3 Injection Molding 344 13.12.4 Rotational Molding 344 13.12.5 Bag Molding 344 13.12.6 Tube Fabrication 345 References 345 14 Polymers for Special Applications 347 14.1 Electrically Conductive Polymers 347 14.1.1 Ionic Conduction in Solid Polymers 348 14.1.2 Proton Conductors 349 14.1.3 Electronically Conducting Polymers 350 14.1.4 Optical and Electro-optical Devices 351 14.1.5 “Linear” Optical Materials 351 14.1.6 Non-linear Optical Polymers 352 14.1.7 Photovoltaic Cells 352 14.2 High-performance Thermoplastics 353 14.3 Polymers for Hydrogen Storage 355 14.4 Smart Materials 357 14.4.1 Introduction 357 14.4.2 Self-healing Polymers 358 14.4.3 Shape-memory Polymers 360 14.5 Uses of Polymers in Biomedicine 362 14.5.1 Cardiovascular Applications 363 14.5.2 Stents and Stenting 365 14.5.3 Tissue Adhesives and Artificial Skin 367 14.5.4 Bones, Joints, and Teeth 368 14.5.5 Contact Lenses and Intraocular Lenses 368 14.6 Tissue Engineering 369 14.7 Controlled Release of Drugs 372 References and Sources for Part Four 373 Index 375