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Mechanical Behavior of Materials by Keith Bowman (2003, Trade Paperback)
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About this product
Product Identifiers
PublisherWiley & Sons, Incorporated, John
ISBN-100471241989
ISBN-139780471241980
eBay Product ID (ePID)2214839
Product Key Features
Number of Pages348 Pages
Publication NameMechanical Behavior of Materials
LanguageEnglish
Publication Year2003
SubjectMaterials Science / General, Orthopedics
TypeTextbook
AuthorKeith Bowman
Subject AreaTechnology & Engineering, Medical
FormatTrade Paperback
Dimensions
Item Height0.7 in
Item Weight26.1 Oz
Item Length10.3 in
Item Width7.2 in
Additional Product Features
Intended AudienceCollege Audience
LCCN2004-299135
Dewey Edition22
IllustratedYes
Dewey Decimal620.1/1292
Table Of ContentChapter 1. Introduction. 1.1 Strain 1.2 Stress. 1.3 Mechanical Testing. 1.4 Mechanical Responses to Deformation. 1.5 How Bonding Influences Mechanical Properties. 1.6 Further Reading and References. 1.7 Problems. Chapter 2. Tensors and Elasticity. 2.1 What Is a Tensor? 2.2 Transformation of Tensors. 2.3 The Second-Rank Tensors of Strain and Stress. 2.4 Directional Properties. 2.5 Elasticity. 2.6 Effective Properties of Materials: Oriented Polycrystals and Composites. 2.7 Matrix Methods for Elasticity Tensors. 2.8 Appendix: The Stereographic Projection. 2.9 References. 2.10 Problems. Chapter 3. Plasticity. 3.1 Continuum Models for Shear Deformation of Isotropic Ductile Materials. 3.2 Shear Deformation of Crystalline Materials. 3.3 Necking and Instability. 3.4 Shear Deformation of Non-Crystalline materials. 3.5 Dilatant Deformation of Materials. 3.6 Appendix: Independent Slip Systems. 3.7 References. 3.8 Problems. Chapter 4. Dislocations in Crystals. 4.1 Dislocation Theory. 4.2 Specification of Dislocation Character. 4.3 Dislocation Motion. 4.4 Dislocation Content in Crystals and Polycrystals. 4.5 Dislocations and Dislocation Motion in Specific Crystal Structures. 4.6 References. 4.7 Problems. Chapter 5. Strengthening Mechanisms. 5.1 "Constraint" -Based Strengthening. 5.2 Strengthening Mechanisms in Crystalline Materials. 5.3 Orientation Strengthening. 5.4 References. 5.5 Problems. Chapter 6. High Temperature and Rate Dependent Deformation. 6.1 Creep. 6.2 Extrapolation Approaches for Failure and Creep. 6.3 Stress Relaxation. 6.4 Creep and Relaxation Mechanisms in Crystalline Materials. 6.5 References. 6.6 Problems. Chapter 7. Fracture of Materials. 7.1 Stress Distributions Near Crack Tips. 7.2 Fracture Toughness Testing. 7.3 Failure Probability and Weibull Statistics. 7.4 Mechanisms for Toughness Enhancement of Brittle Materials. 7.5 Appendix A: Derivation of the Stress Concentration at a Through-Hole. 7.6 Appendix B: Stress-Volume Integral Approach for Weibull Statistics. 7.7 References. 7.8 Problems. Chapter 8. Mapping Strategies for Understanding Mechanical Properties. 8.1 Deformation Mechanism Maps. 8.2 Fracture Mechanism Maps. 8.3 Mechanical Design Maps. 8.4 References. 8.5 Problems. Chapter 9. Degradation Processes: Fatigue and Wear. 9.1 Cystic Fatigue of materials. 9.2 Engineering Fatigue Analysis. 9.3 Wear, Friction, and Lubrication. 9.4 References. 9.5 Problems. Chapter 10. Deformation Processing. 10.1 Ideal Energy Approach for Modeling of a Forming Process. 10.2 Inclusion of Friction and Die Geometry in Deformation Processes: Slab Analysis. 10.3 Upper Bound Analysis. 10.4 Slip Line Field Analysis. 10.5 Formation of Aluminum Beverage Cans: Deep Drawing, Ironing, and Shaping. 10.6 Forming and Rheology of Glasses and Polymers. 10.7 Tape Casting of Ceramic Slurries. 10.8 References. 10.9 Problems. Index.
SynopsisAn understanding of mechanisms for mechanical behavior is essential to applications of new materials and new designs using established materials. Focusing on the similarities and differences in mechanical response within and between the material classes, this book provides a balanced approach between practical engineering applications and the science behind mechanical behavior of materials. Covering the three main material classes: metals, ceramics and polymers, topics covered include stress, strain, tensors, elasticity, dislocations, strengthening mechanisms, high temperature deformation, fracture, fatigue, wear and deformation processing., An understanding of mechanisms for mechanical behavior is essential to applications of new materials and new designs using established materials., An understanding of mechanisms for mechanical behavior is essential to applications of new materials and new designs using established materials. Focusing on the similarities and differences in mechanical response within and between the material classes, this book provides a balanced approach between practical engineering applications and the science behind mechanical behavior of materials. Covering the three main material classes: metals, ceramics and polymers, topics covered include stress, strain, tensors, elasticity, dislocations, strengthening mechanisms, high temperature deformation, fracture, fatigue, wear and deformation processing. Designed to provide a bridge between introductory coverage of materials science and strength of materials books and specialized treatments on elasticity, deformation and mechanical processing, this title: * Successfully employs the principles of physics and mathematics to the materials science topics covered. * Provides short biographical or historical background on key contributors to the field of materials science. * Includes over one hundred new figures and mechanical test data that illustrate the subjects covered. * Features numerous examples and more than 150 homework problems, with problems pitched at three levels., Explore Mechanical Behavior in a Rich Practical and Historical Context With Keith Bowman s An Introduction to Mechanical Behavior of Materials , you can build a sound understanding of the mechanisms for mechanical behavior essential knowledge that will help you successfully apply new materials and new designs using established materials. Focusing on the similarities and differences in mechanical response within and between the material classes, the text provides a balanced approach between practical engineering applications and the science behind the mechanical behavior of materials. Coverage spans the three main material classes (metals, ceramics, and polymers), as well as a broad range of topics, including stress, strain, tensors, elasticity, dislocations, strengthening mechanisms, high-temperature deformation, fracture, fatigue, wear, and deformation processing. Features Examples of engineering applications provide a practical context for the material. Numerical solutions demonstrate the mathematics behind key concepts. Provides a bridge between introductory coverage of materials science and strength of materials books and specialized treatments on elasticity, deformation, and mechanical processing. Presents short biographical or historical background on key contributors to the field of materials science. Includes over 100 figures and mechanical test data specifically created for this new text. Contains numerous examples and more than 150 homework problems of varying complexity. Appendices provide derivations and background tutorials.
LC Classification NumberTA405.B686 2004
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