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Chapter 7 Continued Cover Eqs. 7.1 through 7.6

Chapter 7 Continued Cover Eqs. 7.1 through 7.6. Solid-Solution Strengthening (III). Strengthening by increase of dislocation density (Strain Hardening = Work Hardening = Cold Working). Ductile metals strengthen when deformed plastically at temperatures well below melting point. .

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Chapter 7 Continued Cover Eqs. 7.1 through 7.6

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  1. Chapter 7 Continued Cover Eqs. 7.1 through 7.6

  2. Solid-Solution Strengthening (III)

  3. Strengthening by increase of dislocation density (Strain Hardening = Work Hardening = Cold Working) Ductile metals strengthen when deformed plastically at temperatures well below melting point. Reason  increased dislocation density. Average distance between dislocations decreases; dislocations start blocking each others motion. Percent cold work (%CW)degree of plastic deformation: where A0 is the original cross-section area, Ad is the area after deformation. %CW another measure of degree of plastic deformation, like strain.

  4. Strain Hardening (II) New yield strength yihigher than initial yield strength, y0. Reason strain hardening.

  5. Strain Hardening (III) Yield strength + hardness increased due tostrain hardening,but ductility decreased (material becomes more brittle).

  6. Strain Hardening (IV)

  7. Recovery, Recrystallization, and Grain Growth • Plastic deformation increases dislocation density + changes grain size distribution • Therefore, stored strain energy (dislocation strain fields + grain distortions) • External stress removed: most dislocations, grain distortions and associated strain energy retained. • Restoration to state before cold-work by heat-treatment:  Recovery and Recrystallization, followed by grain growth.

  8. Recovery Heating increased diffusion  enhanced dislocation motion  decrease in dislocation density by annihilation, formation of low-energy dislocation configurations  relieves internal strain energy Some of the mechanisms of dislocation annihilation: Edge dislocation slip plane vacancies

  9. Recrystallization (I) • After recovery grains can still be strained. Strained grains replaced upon heating by strain-free grains with low density of dislocations. • Recrystallization: nucleation and growth of new grains • Driving force: difference in internal energy between strained and unstrained • Grain growth short-range diffusion Extent of recrystallization depends on temperature and time. • Recrystallization is slowerin alloys

  10. Recrystallization (II) Recrystallization temperature: temperature at which process is complete in one hour. Typically 1/3 to 1/2 of melting temperature (can be as high as 0.7 Tm in some alloys). Recrystallization decreases as %CW is increased. Below "critical deformation", recrystallization does not occur.

  11. Recrystallization (III)

  12. Grain Growth • Deformed polycrystalline material maintained at annealing temperature  following recrystallization further grain growth occurs • Driving force: reduction of grain boundary area and energy: Big grains grow at the expense of small ones • Grain growth during annealing occurs in all polycrystalline materials (i.e. they do not have to be deformed first). • Boundary motion occurs by short range diffusion of atoms across the grain boundary strong temperature dependence of the grain growth.

  13. Summary Make sure you understand language and concepts: • Cold working • Critical resolved shear stress • Dislocation density • Grain growth • Lattice strain • Recovery • Recrystallization • Recrystallization temperature • Resolved shear stress • Slip • Slip system • Strain hardening • Solid-solution strengthening

  14. Reading for next class: • Chapter 8:Failure • Mechanisms of brittle vs. ductile fracture • Impact fracture testing • Fatigue (cyclic stresses) • Crack initiation and propagation • Creep (time dependent deformation) • Optional reading (Parts that are not covered / not tested): • Parts of 8.5 Principles of fracture mechanics • 8.10 Crack propagation rate • 8.16 Data extrapolation methods

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