1. Fracture Mechanic Dr.Behzad Heidar shenas

2. Course Outline -An overview on the materials characteristics: 1.Types of crystal structures 2. Defects 3.Stress-Strain diagram evaluation -Destructive examination -Concept of Fracture -Fracture mechanic -Fatigue failure -Scc fatigue corrosion -Creep -Design and failure analysis -NDT * Book: Deformation and Fracture Mechanics of Engineering Materials, Richard W.Hertzberg, Fifth Edition -An overview on the materials characteristics: 1.Types of crystal structures 2. Defects 3.Stress-Strain diagram evaluation -Destructive examination -Concept of Fracture -Fracture mechanic -Fatigue failure -Scc fatigue corrosion -Creep -Design and failure analysis -NDT * Book: Deformation and Fracture Mechanics of Engineering Materials, Richard W.Hertzberg, Fifth Edition

3. Assessment -Attendance: 10% -Quiz (2): 15% -Midterm: 30% -Project: 10% -Final: 35% -Attendance: 10% -Quiz (2): 15% -Midterm: 30% -Project: 10% -Final: 35%

4. Engineering Materials

5. The Structure of Metals Figure 1.1 An outline of the topics described in Chapter 1.

6. Crystal Structure of Metals Body-centered cubic (BCC) - alpha iron, chromium, molybdenum, tantalum, tungsten, and vanadium. Face-centered cubic (FCC) - gamma iron, aluminum, copper, nickel, lead, silver, gold and platinum. Hexagonal close-packed - beryllium, cadmium, cobalt, magnesium, alpha titanium, zinc and zirconium. Common crystal structures for metals:

7. Body-Centered Cubic Crystal Structure Example: Iron (Fe) Good strength Moderate ductivity The body-centered cubic (bcc) crystal structure: (a) hard-ball model; (b) unit cell; and (c) single crystal with many unit cells

8. Face-Centered Cubic Crystal Structure Example: Aluminum (Al) Moderate strength Good ductivity The face-centered cubic (fcc) crystal structure: (a) hard-ball model; (b) unit cell; and (c) single crystal with many unit cells

9. Hexagonal Close-Packed Crystal Structure Example: Beryllium, Zinc Low strength Low ductivity The hexagonal close-packed (hcp) crystal structure: (a) unit cell; and (b) single crystal with many unit cells

10. Solidification (a)Nucleation of crystals at random sites in the molten metal; note that the crystallographic orientation of each site is different. (b) and (c) Growth of crystals as solidification continues. (d) Solidified metal, showing individual grains and grain boundaries; note the different angles at which neighboring grains meet each other. Schematic illustration of the stages during solidification of molten metal; each small square represents a unit cell. Grain boundary Volume imperfection voids inclusions Plane imperfection

11. Solidification of Molten Metal Schematic illustration of the stages during solidification of molten metal; each small square represents a unit cell. (a) Nucleation of crystals at random sites in the molten metal; note that the crystallographic orientation of each site is different. (b) and (c) Growth of crystals as solidification continues. (d) Solidified metal, showing individual grains and grain boundaries; note the different angles at which neighboring grains meet each other.

12. Imperfections

13. Defects in a Single-Crystal Lattice (point imperfections) Schematic illustration of types of defects in a single-crystal lattice: self-interstitial, vacancy, interstitial, and substitutional.

14. Deformation Mechanisms Cubic metals readily deform by plastic shear or slip. Sliping: one plane of atoms slides over the next adjacent plane. Shear deformation also occurs when compression or tension forces are applies

15. Permanent Deformation Figure 1.5 Permanent deformation (also called plastic deformation) of a single crystal subjected to a shear stress: (a) structure before deformation; and (b) permanent deformation by slip. The b/a ratio influences the magnitude of the shear stress required to cause slip.

17. Mechanism of slip The strength of metals = shear modulus/6

19. Slip by Dislocation

20. Movement of Dislocation (line imperfection) Movement of an edge dislocation across the crystal lattice under a shear stress. Dislocations help explain why the actual strength of metals in much lower than that predicted by theory.

21. If we place a shear stress along the horizontal direction, the dislocation can be moved with shearing displacement within the crystal. The slip mechanism requires energy, E  IGb 2

25. Plastic deformation of compounds In Metals : each atom is surrounded by similar atoms. In compounds: two or more atom types are there, deformation brings like atoms together and separates a fraction on unlike atoms High Energy is required (resistance to shear)

26. Plastic deformation of compounds