Fracture mechanics : fundamentals and applications

With its combination of practicality, readability, and rigor that is characteristic of any truly authoritative reference and text, Fracture Mechanics: Fundamentals and Applications quickly established itself as the most comprehensive guide to fracture mechanics available. It has been adopted by more than 100 universities and embraced by thousands of professional engineers worldwide. Now in its third edition, the book continues to raise the bar in both scope and coverage. It encompasses theory and applications, linear and nonlinear fracture mechanics, solid mechanics, and materials science with a unified, balanced, and in-depth approach. Reflecting the many advances made in the decade since the previous edition came about, this indispensable Third Edition now includes: A new chapter on environmental cracking Expanded coverage of weight functions New material on toughness test methods New problems at the end of the book New material on the failure assessment diagram (FAD) method Expanded and updated coverage of crack closure and variable-amplitude fatigue Updated solutions manual In addition to these enhancements, Fracture Mechanics: Fundamentals and Applications, Third Edition also includes detailed mathematical derivations in appendices at the end of applicable chapters; recent developments in laboratory testing, application to structures, and computational methods; coverage of micromechanisms of fracture; and more than 400 illustrations. This reference continues to be a necessity on the desk of anyone involved with fracture mechanics.

INTRODUCTION History and Overview Why Structures Fail Historical Perspective The Fracture Mechanics Approach to Design Effect of Material Properties on Fracture A Brief Overview of Dimensional Analysis References FUNDAMENTAL CONCEPTS Linear Elastic Fracture Mechanics An Atomic View of Fracture Stress Concentration Effect of Flaws The Griffith Energy Balance The Energy Release Rate Instability and the R Curve Stress Analysis of Cracks Relationship Between K and G Crack-Tip Plasticity K-Controlled Fracture Plane Strain Fracture: Fact Versus Fiction Mixed-Mode Fracture Interaction of Multiple Cracks Appendix 2: Mathematical Foundations of Linear Elastic Fracture Mechanics References Elastic-Plastic Fracture Mechanics Crack-Tip-Opening Displacement The J Contour Integral Relationships Between J and CTOD Crack-Growth Resistance Curves J-Controlled Fracture Crack-Tip Constraint Under Large-Scale Yielding Appendix 3: Mathematical Foundations of Elastic-Plastic Fracture Mechanics References Dynamic and Time-Dependent Fracture Dynamic Fracture and Crack Arrest Creep Crack Growth Viscoelastic Fracture Mechanics Appendix 4: Dynamic Fracture Analysis References MATERIAL BEHAVIOR Fracture Mechanisms in Metals Ductile Fracture Cleavage The Ductile-Brittle Transition Intergranular Fracture Appendix 5: Statistical Modeling of Cleavage Fracture References Fracture Mechanisms in Nonmetals Engineering Plastics Ceramics and Ceramic Composites Concrete and Rock References APPLICATIONS Fracture Toughness Testing of Metals General Considerations Klc Testing K-R Curve Testing J Testing of Metals CTOD Testing Dynamic and Crack-Arrest Toughness Fracture Testing of Weldments Testing and Analysis of Steels in the Ductile-Brittle Transition Region Qualitative Toughness Tests Appendix 7: Stress Intensity, Compliance, and Limit Load Solutions for Laboratory Specimens References Fracture Testing of Nonmetals Fracture Toughness Measurements in Engineering Plastics Interlaminar Toughness of Composites Ceramics References Application to Structures Linear Elastic Fracture Mechanics The CTOD Design Curve Elastic-Plastic J-Integral Analysis Failure Assessment Diagrams Probabilistic Fracture Mechanics Appendix 9: Stress Intensity and Fully Plastic J Solutions for Selected Configurations References Fatigue Crack Propagation Similitude in Fatigue Empirical Fatigue Crack Growth Equations Crack Closure The Fatigue Threshold Variable Amplitude Loading and Retardation Growth of Short Cracks Micromechanisms of Fatigue Fatigue Crack Growth Experiments Damage Tolerance Methodology Appendix 10: Application of the J Contour Integral to Cyclic Loading References Environmentally Assisted Cracking in Metals Corrosion Principles Environmental Cracking Overview Stress Corrosion Cracking Hydrogen Embrittlement Corrosion Fatigue Experimental Methods References Computational Fracture Mechanics Overview of Numerical Methods Traditional Methods in Computational Fracture Mechanics The Energy Domain Integral Mesh Design Linear Elastic Convergence Study Analysis of Growing Cracks Appendix 12: Properties of Singularity Elements References Practice Problems Index