Thoroughly updated, Introduction to Polymers (Third Edition) presents the science underpinning the synthesis, characterization and properties of polymers. The material has been completely reorganized and expanded to include important new topics and provide a coherent platform for teaching and learning the fundamental aspects of contemporary polymer science.
New to the Third Edition
Part I
This first part covers newer developments in polymer synthesis, including 'living' radical polymerization, catalytic chain transfer and free-radical ring-opening polymerization, along with strategies for the synthesis of conducting polymers, dendrimers, hyperbranched polymers and block copolymers. Polymerization mechanisms have been made more explicit by showing electron movements.
Part II
In this part, the authors have added new topics on diffusion, solution behaviour of polyelectrolytes and field-flow fractionation methods. They also greatly expand coverage of spectroscopy, including UV visible, Raman, infrared, NMR and mass spectroscopy. In addition, the Flory-Huggins theory for polymer solutions and their phase separation is treated more rigorously.
Part III
A completely new, major topic in this section is multicomponent polymer systems. The book also incorporates new material on macromolecular dynamics and reptation, liquid crystalline polymers and thermal analysis. Many of the diagrams and micrographs have been updated to more clearly highlight features of polymer morphology.
Part IV
The last part of the book contains major new sections on polymer composites, such as nanocomposites, and electrical properties of polymers. Other new topics include effects of chain entanglements, swelling of elastomers, polymer fibres, impact behaviour and ductile fracture. Coverage of rubber-toughening of brittle plastics has also been revised and expanded.
While this edition adds many new concepts, the philosophy of the book remains unchanged. Largely self-contained, the text fully derives most equations and cross-references topics between chapters where appropriate. Each chapter not only includes a list of further reading to help readers expand their knowledge of the subject but also provides problem sets to test understanding, particularly of numerical aspects.
By:
Robert J Young,
Peter A Lovell
Imprint: CRC Press
Country of Publication: United States
Edition: 3rd New edition
Dimensions:
Height: 254mm,
Width: 178mm,
Spine: 38mm
Weight: 1.236kg
ISBN: 9780849339295
ISBN 10: 0849339294
Pages: 688
Publication Date: 27 June 2011
Audience:
College/higher education
,
Primary
Format: Paperback
Publisher's Status: Active
CONCEPTS, NOMENCLATURE AND SYNTHESIS OF POLYMERS Concepts and Nomenclature The Origins of Polymer Science and the Polymer Industry Basic Definitions and Nomenclature Molar Mass and Degree of Polymerization Principles of Polymerization Introduction Classification of Polymerization Reactions Monomer Functionality and Polymer Skeletal Structure Functional Group Reactivity and Molecular Size: The Principle of Equal Reactivity Step Polymerization Introduction Linear Step Polymerization Non-Linear Step Polymerization Radical Polymerization Introduction to Radical Polymerization The Chemistry of Conventional Free-Radical Polymerization Kinetics of Conventional Free-Radical Polymerization Free-Radical Polymerization Processes Reversible-Deactivation (`Living') Radical Polymerizations Non-Linear Radical Polymerizations Ionic Polymerization Introduction to Ionic Polymerization Cationic Polymerization Anionic Polymerization Group-Transfer Polymerization Stereochemistry and Coordination Polymerization Introduction to Stereochemistry of Polymerization Tacticity of Polymers Geometric Isomerism in Polymers Prepared from Conjugated Dienes Ziegler-Natta Coordination Polymerization Metallocene Coordination Polymerization Ring-Opening Polymerization Introduction to Ring-Opening Polymerization Cationic Ring-Opening Polymerization Anionic Ring-Opening Polymerization Free-Radical Ring-Opening Polymerization Ring-Opening Metathesis Polymerization Specialized Methods of Polymer Synthesis Introduction Solid-State Topochemical Polymerization Polymerization by Oxidative Coupling Precursor Routes to Intractable Polymers Supramolecular Polymerization (Polyassociation) Copolymerization Introduction Step Copolymerization Chain Copolymerization Block Copolymer Synthesis Graft Copolymer Synthesis CHARACTERIZATION OF POLYMERS Theoretical Description of Polymers in Solution Introduction Thermodynamics of Polymer Solutions Chain Dimensions Frictional Properties of Polymer Molecules in Dilute Solution Number-Average Molar Mass Introduction to Measurements of Number-Average Molar Mass Membrane Osmometry Vapour Pressure Osmometry Ebulliometry and Cryoscopy End-Group Analysis Effects of Low Molar Mass Impurities upon Mn Scattering Methods Introduction Static Light Scattering Dynamic Light Scattering Small-Angle X-Ray and Neutron Scattering Frictional Properties of Polymers in Solution Introduction Dilute Solution Viscometry Ultracentrifugation Molar Mass Distribution Introduction Fractionation Gel Permeation Chromatography Field-Flow Fractionation Mass Spectroscopy Chemical Composition and Molecular Microstructure Introduction Principles of Spectroscopy Ultraviolet and Visible Light Absorption Spectroscopy Infrared Spectroscopy Raman Spectroscopy Nuclear Magnetic Resonance Spectroscopy Mass Spectroscopy PHASE STRUCTURE AND MORPHOLOGY OF BULK POLYMERS The Amorphous State Introduction The Glass Transition Factors Controlling the Tg Macromolecular Dynamics The Crystalline State Introduction Determination of Crystal Structure Polymer Single Crystals Semi-Crystalline Polymers Liquid Crystalline Polymers Defects in Crystalline Polymers Crystallization Melting Multicomponent Polymer Systems Introduction Polymer Blends Block Copolymers PROPERTIES OF BULK POLYMERS Elastic Deformation Introduction Elastic Deformation Elastic Deformation of Polymers Viscoelasticity Introduction Viscoelastic Mechanical Models Boltzmann Superposition Principle Dynamic Mechanical Testing Frequency Dependence of Viscoelastic Behaviour Transitions and Polymer Structure Time-Temperature Superposition Effect of Entanglements Non-Linear Viscoelasticity Elastomers Introduction Thermodynamics of Elastomer Deformation Statistical Theory of Elastomer Deformation Stress-Strain Behaviour of Elastomers Factors Affecting Mechanical Behaviour Yield and Crazing Introduction Phenomenology of Yield Yield Criteria Deformation Mechanisms Crazing Fracture and Toughening Introduction Fundamentals of Fracture Mechanics of Fracture Fracture Phenomena Toughened Polymers Polymer Composites Introduction to Composite Materials Matrix Materials Types of Reinforcement Composite Composition Particulate Reinforcement Fibre Reinforcement Nanocomposites Electrical Properties Introduction to Electrical Properties Dielectric Properties Conduction in Polymers Polymer Electronics Answers to Problems Index Problems and Further Reading appear at the end of each chapter.
Robert J. Young is a professor of polymer science and technology at the University of Manchester and a Fellow of the Royal Academy of Engineering. He has published extensively and is listed on ISIHighlyCited.com. His research focuses on the relationships between structure and properties in polymers and composites. Peter A. Lovell is a professor of polymer science at the University of Manchester. His research and publications focus on aspects of emulsion polymerization and related processes, especially in relation to understanding how to control the chemical structure, morphology and properties of the polymers produced.
Reviews for Introduction to Polymers (3rd Edition)
The second edition of this book is currently the recommended text for a second year undergraduate lecture course I deliver. In future I will recommend the third edition for both this course and a fourth year (Masters) lecture course on advanced polymer synthesis. Moreover, not only have Young and Lovell produced an excellent text (again) for supporting undergraduate teaching, this book is also a superb entry level text for postgraduates students with limited experience of polymers. —Chemistry World, 2012
