Deformation and Fracture Mechanics of Engineering Materials, 5th EditionDeformation and Fracture Mechanics of Engineering Materials provides a combined fracture mechanics-materials approach to the fracture of engineering solids with comprehensive treatment and detailed explanations and references, making it the perfect resource for senior and graduate engineering students, and practicing engineers alike. The 5th edition includes new end-of-chapter homework problems, examples, illustrations, and a new chapter on products liability and recall addressing the associated social consequences of product failure. The new edition continues to discuss actual failure case histories, and includes new discussion of the fracture behavior and fractography of ceramics, glasses, and composite materials, and a section on natural materials including bone and sea shells. New co-authors Richard P. Vinci and Jason L. Hertzberg add their talent and expertise to broaden the book's perspective, while maintaining a balance between the continuum mechanics understanding of the failure of solids and the roles of the material's nano- and microstructure as they influence the mechanical properties of materials. |
Contents
FRACTURE MECHANICS OF ENGINEERING MATERIALS | 249 |
FRACTURE SURFACE PRESERVATION CLEANING AND REPLICATION TECHNIQUES AND IMAGE INTERPRETATION | 713 |
K CALIBRATIONS FOR TYPICAL FRACTURE TOUGHNESS AND FATIGUE CRACK PROPAGATION TEST SPECIMENS | 719 |
Y CALIBRATION FACTORS FOR ELLIPTICAL AND SEMICIRCULAR SURFACE FLAWS | 723 |
SUGGESTED CHECKLIST OF DATA DESIRABLE FOR COMPLETE FAILURE ANALYSIS | 725 |
Author Index | 729 |
Materials Index | 741 |
Subject Index | 747 |
Other editions - View all
Deformation and Fracture Mechanics of Engineering Materials Richard W. Hertzberg,Richard P. Vinci,Jason L. Hertzberg No preview available - 2012 |
Common terms and phrases
alloy aluminum alloy applied stress associated ASTM International ASTM STP atoms axis behavior brittle Burgers vector ceramic Chapter component composite compressive configuration corrosion crack growth rate crack length crack propagation crack tip creep crystal curve cycles cyclic decrease defined determined dislocation ductility elastic embrittlement energy engineering failure fatigue crack fiber Figure final first flaw flow fracture mechanics fracture surface fracture toughness glass grain boundary hydrogen identified increasing influence initial Kmax lattice load material matrix metals microstructure modulus notch occur orientation particles plastic deformation plastic zone plate polymer product recall R. W. Hertzberg recall reflect region Reprinted with permission result sample screw dislocation Section shear stress shown in Fig significant specific specimen stacking fault energy strain rate stress concentration stress field stress intensity factor stress level structure superalloys tensile thermal thickness toughening twin values yield strength