The Elements of Polymer Science & Engineering

The Elements of Polymer Science & Engineering, 3rd Edition

The Elements of Polymer Science & Engineering, 3rd Edition,Alfred Rudin,Phillip Choi,ISBN9780123821782


Academic Press




235 X 191

A classic textbook on polymer science and engineering; fully revised with strong teaching pedagogy and updated with the latest developments on contemporary topics such as behavior of natural polymers, polymer nanocomposites, and the use of polymers in nanotechnology, to appeal to instructors and students in a variety of disciplines

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Key Features

    Hallmark features:

    • Focuses on applications of polymer chemistry, engineering, and technology
    • Explains terminology, applications, and versatility of synthetic polymers
    • Connects polymerization chemistry with engineering applications
    • Contains practical lead-ins to emulsion polymerization, viscoelasticity, and polymer rheology


    Whether you are an upper or graduate level student studying polymer science and engineering or an engineer new to the field of polymers, you'll benefit from reading The Elements of Polymer Science and Engineering 3e. Since the publication of the second edition in 1999, the field of polymers has advanced considerably. A key feature of the third edition is the inclusion of new concepts in existing chapters as well as new chapters covering selected contemporary topics such as behavior of natural polymers, polymer nanocomposites, and use of polymers in nanotechnology. There are also several enhancements to the book’s pedagogy, including the addition of numerous worked examples and new figures to better illustrate key concepts and the addition of a large number of end-of-chapter exercises, many of which are based on recently published research and relevant industrial data.


    Advanced undergraduate and graduate students in the physics, chemistry, and chemical engineering departments who are taking courses related to polymer science and engineering.

    Alfred Rudin

    Alfred Rudin is a member of the Professional Engineers of Ontario. Professor Rudin spent 14 years with a large Canadian chemical company in research, development, and production. He joined the University of Waterloo chemistry department where he is now a Distinguished Professor Emeritus. He is the author or co-author of 295 research papers and 25 patents. Dr. Rudin is also a fellow of the Chemical Institute of Canada, the Royal Society of Canada, and the Federation of Societies for Coatings Technology.

    Affiliations and Expertise

    University of Waterloo, Ontario, Canada

    View additional works by Alfred Rudin

    Phillip Choi

    Ph.D., P.Eng

    Prof. Phillip Choi received his B.A.Sc. in chemical engineering in 1988 from the University of British Columbia and his M.A.Sc. and Ph.D., also in chemical engineering, in 1992 and 1995, respectively, from the University of Waterloo. While pursuing his graduate studies, he received scholarships from the Federation of Societies for Coatings Technology and the Natural Sciences and Engineering Research Council of Canada to study solubility properties of non-ionic surfactants and polyolefin blends under the guidance of Professor Alfred Rudin and Dr. Tom Kavassalis of Xerox Corporation, currently VP - Strategy Planning. Upon completion of his Ph.D., Prof. Choi worked in the coating industry as a development chemist developing high solids urethane and water-borne epoxy coating formulations. He then joined the Department of Chemical and Materials Engineering at the University of Alberta as a sessional instructor in 1996 and at the same time, carried out research in the area of polymer rheology in Prof. Michael Williams’ lab. In 1997, he became an assistant professor and was promoted to the rank of full professor in 2006. In the 2003/2004 academic year, Prof. Choi spent a one year sabbatical in Prof. Wayne L. Mattice’s lab of the Maurice Morton Institute of Polymer Science at the University of Akron studying crystallization behavior of polypropylene blends using the rotational isomeric state theory. Prof. Choi has supervised 9 postdoctoral fellows as well as 6 Ph.D., 8 M.Sc. and 30 B.Sc. theses over the past ten years. Prof. Choi’s current research interests lie in the areas of molecular simulation of polymers, statistical thermodynamics of polymer solutions and blends, structure-property relationships of branched polyethylene and of block copolymers used in nanoscopic drug delivery systems and adsorption behaviour of polymer on inorganic surfaces. He has published over 100 book chapters, referred journal articles and conference proceedings and is constantly in demand as manuscript reviewer for major polymer and physical science journals and proposal reviewer for various Canadian and American funding agencies. Prof. Choi is also an active consultant to various multinational organizations on issues related to polymer product development. He is currently the chair of the Edmonton section of the Canadian Society for Chemical Engineering and a board of director of the Canadian Society for Chemical Engineering. He is a registered professional engineer in the province of Alberta. Prof. Phillip Choi won the Faculty of Engineering Undergraduate Teaching Award and was named the McCalla Professorship in 2007 at the University of Alberta recognizing his dedication to undergraduate education. In particular, he has accumulated 13 years of experience teaching introductory polymer courses to senior undergraduate and first year graduate students. He received an international IUPAC Travel Award in 2002 and a National Young Innovator Award from Petro Canada Inc. in 2002 and 2001, respectively, recognizing his work on molecular simulation of polymers.

    Affiliations and Expertise

    Professor of Chemical Engineering, Department of Chemical & Materials Engineering, University of Alberta, Edmonton, AB, Canada

    The Elements of Polymer Science & Engineering, 3rd Edition



    In Memoriam for Alfred Rudin (1924–2011)

    Chapter 1. Introductory Concepts and Definitions

    1.1 Some Definitions

    1.2 Degree of Polymerization

    1.3 Polymerization and Functionality

    1.4 Why Are Synthetic Polymers Useful? [3]

    1.5 Copolymers

    1.6 Molecular Architecture

    1.7 Thermoplastics and Thermosets

    1.8 Elastomers, Fibers, and Plastics

    1.9 Miscellaneous Terms

    1.10 Polymer Nomenclature

    1.11 Constitutional Isomerism

    1.12 Configurational Isomerism

    1.13 Polymer Conformation

    1.14 Molecular Dimensions in the Amorphous State


    Chapter 2. Basic Principles of Polymer Molecular Weights

    2.1 Importance of Molecular Weight Control

    2.2 Plan of This Chapter

    2.3 Arithmetic Mean

    2.4 Molecular Weight Averages as Ratios of Moments

    2.5 Breadth of the Distribution

    2.6 Summarizing the Molecular Weight Distribution


    2.8 Integral and Summative Expressions

    2.9 Typical Molecular Weight Distributions

    Appendix 2A


    Chapter 3. Practical Aspects of Molecular Weight Measurements

    3.1 Methods

    3.2 Light Scattering

    3.3 Dilute Solution Viscometry

    3.4 Size Exclusion Chromatography

    Appendix 3A Multigrade Motor Oils [29]


    Chapter 4. Mechanical Properties of Polymer Solids and Liquids

    4.1 Introduction

    4.2 Thermal Transitions

    4.3 Crystallization of Polymers

    4.4 The Glass Transition

    4.5 Rubber Elasticity

    4.6 Rodlike Macromolecules

    4.7 Polymer Viscoelasticity

    4.8 Dynamic Mechanical Behavior at Thermal Transitions

    4.9 Stress–Strain Tests

    4.10 Crazing in Glassy Polymers

    4.11 Fracture Mechanics

    4.12 Toughness and Brittleness

    4.13 Rheology

    4.14 Effects of Fabrication Processes


    Chapter 5. Polymer Mixtures

    5.1 Compatibility

    5.2 Thermodynamic Theories

    5.3 Solvents and Plasticizers

    5.4 Fractionation

    5.5 Practical Aspects of Polymer Blending [19]

    5.6 Reinforced Elastomers

    5.7 Reinforced Plastics


    Chapter 6. Diffusion in Polymers

    6.1 Introduction

    6.2 Fick’s Laws

    6.3 Diffusion Coefficients

    6.4 Mutual Diffusion

    6.5 Self-Diffusion of Polymer Chains in Dilute Polymer Solutions

    6.6 Self-Diffusion of Solvent in Polymers


    Chapter 7. Step-Growth Polymerizations

    7.1 Condensation and Addition Polymers

    7.2 Step-Growth and Chain-Growth Polymerizations

    7.3 Requirements for Step-Growth Polymerization

    7.4 Polymer Size and Extent of Conversion of Functional Groups in Equilibrium Step-Growth Polymerizations

    7.5 Interfacial and Solution Polymerizations of Acid Chlorides and Other Reactive Monomers

    7.6 Step-Growth Copolymerizations


    Chapter 8. Free-Radical Polymerization

    8.1 Scope

    8.2 Polymerizability of Monomers

    8.3 Overall Kinetics of Radical Polymerization

    8.4 A Note on Termination Rate Constants

    8.5 Methods of Producing Radicals

    8.6 Length of the Kinetic Chain and Number Average Degree of Polymerization of the Polymer

    8.7 Modes of Termination

    8.8 Chain Transfer

    8.9 Inhibition and Retardation

    8.10 Readily Observable Features of Free-Radical Polymerizations

    8.11 Radical Lifetimes and Concentrations

    8.12 Determination of kp and kt

    8.13 Deviations from Ideal Kinetics

    8.14 Molecular Weight Distribution

    8.15 Free-Radical Techniques for Polymers with Narrower Molecular Weight Distributions

    8.16 Effects of Temperature

    8.17 Free-Radical Polymerization Processes


    Chapter 9. Copolymerization

    9.1 Chain-Growth Copolymerization

    9.2 Simple Copolymer Equation

    9.3 Copolymer Structure Inferences from Reactivity Ratios

    9.4 Azeotropic Compositions

    9.5 Integrated Binary Copolymer Equation

    9.6 Determination of Reactivity Ratios

    9.7 Multicomponent Copolymerizations

    9.8 Sequence Distribution in Copolymers

    9.9 Gel Formation During Copolymerization and Cross-Linking [22]

    9.10 Reactivities of Radicals and Monomers

    9.11 Analysis of Reactivity Data

    9.12 Effect of Reaction Conditions

    9.13 Rates of Free-Radical Copolymerizations

    9.14 Alternative Copolymerization Models


    Chapter 10. Dispersion and Emulsion Polymerizations

    10.1 Dispersion Polymerization

    10.2 Emulsion Polymerization

    10.3 Other Ingredients in Emulsion Recipes

    10.4 Emulsion Polymerization Processes


    Chapter 11. Ionic and Coordinated Polymerizations

    11.1 Comparison of Ionic and Free-Radical Polymerizations

    11.2 Anionic Polymerization

    11.3 Group Transfer Polymerization

    11.4 Cationic Polymerization

    11.5 Coordination Polymerization

    11.6 Olefin Metathesis Catalysts


    Chapter 12. Polymer Reaction Engineering

    12.1 Scope

    12.2 Step-Growth Polymerizations

    12.3 Chain-Growth Polymerizations

    12.4 Homogeneous and Heterogeneous Polymerization Processes

    12.5 Batch, Semibatch, and Continuous Processes

    12.6 Polymerization Reactors


    Chapter 13. Biopolymers

    13.1 Introduction

    13.2 Natural Polymers

    13.3 Bio-Based Polymers (Bioplastics)

    13.4 Biopolymer Blends and Biocomposites

    13.5 Future of Bioplastic Products


    Appendix A. Conversion of Units

    Appendix B. List of Symbols


    Quotes and reviews

    @qu:"The textbook has been a solid teaching text for introductory polymer science and engineering courses....It remains a very good textbook for many introductory concepts and is thought out and developed well for teaching purposes."
    @source:--Eli Pearce, Polytechnicnic University, Brooklyn, NY, POLYMER NEWS, Vol. 24, No. 10, 1999.
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