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Strengthening of Crystalline Materials

Strengthening of Crystalline Materials. Dr. Richard Chung Department of Chemical and Materials Engineering San Jose State University. Learning Objectives. List and explain different strengthening mechanisms in a crystalline materials Discuss the methods to decrease the dislocation mobility

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Strengthening of Crystalline Materials

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  1. Strengthening of Crystalline Materials Dr. Richard Chung Department of Chemical and Materials Engineering San Jose State University

  2. Learning Objectives • List and explain different strengthening mechanisms in a crystalline materials • Discuss the methods to decrease the dislocation mobility • Identify various types of obstacles and discuss the interactions among them • Explain how dislocations will pass through strong or weak obstacles (obstacle spacing and angle) • Discuss the factors associated with the strengthening mechanisms – grain boundaries, grain size, plastic deformation, second phase, interstitial sites, etc.

  3. Movement of A Dislocation t A B L L x t

  4. The force acting on the dislocation per unit length is simply the product of two terms: shear stress and Burgers vector • The tension of the dislocation line (a change of strain energy) is defined as Gb2

  5. Dislocation Positions Associated with A Frank-Read Source The following figures are selected from Barrett, Carig et al. The Principles of Engineering Materials, prentice-Hall, 1973, p.244.

  6. A Frank-Read Source in Silicon

  7. Restricting the Motion of A Dislocation • The flow stress is increased when a dislocation encounters an array of obstacles.

  8. c is a critical extrusion angle • c is smallwhen the obstacles are strong; c is big (180o)when the obstacles are weak

  9. Work Hardening • Work hardening will increase the density of dislocation in a material • The flow stress is determined by the spacing between active slip planes and the overall dislocation density • The governing equation is expressed as: where  is an empirical constant, o is the intrinsic strength of a material with low dislocation density

  10. Resloved Shear Stress Dislocation Density Resloved Shear Stress

  11. Cell Size Effect • Cell structure is developed due to the plastic strain created in a local area where different types of dislocation patterns emerge on multiple slip systems • The boundaries of a cell structure contains many dislocations. However, there are no dislocations discovered inside the cell. • The relationship between applied shear stress and the cell size are written as:

  12. Boundary Strengthening • Boundaries are strong obstacles to dislocation motion • Microscopic yielding develops in a material due to dislocations piled up against the grain boundary in a grain • Macroscopic yielding develops when the dislocations are activated by the adjacent grains. • Hall-Petch equations: d is the grain diameter

  13. Atomic size (Solute vs. Solvent) • Interaction between a moving dislocation and solute atoms depends on the local volume change. • If a smaller atom resides above a slip plane, a moving dislocation will encounter a negative dislocation interaction energy due to reduction in volume.  Dislocation is attracted to the solute atom. • On the contrary, the dislocation would be repelled by the solute atom, if were placed below the slip plane.

  14. Strains Associated with Structure Change BCT?

  15. Modulus Effect • Dislocation energy is proportional to shear modulus and to the Burgers vector surrounded Us1/2 Gb2 • The modulus effect does not depend on the position of the solute atoms • Dislocation energy will be reinforced or impaired depends on the modulus and size effects (hard or soft atoms) • A soft atom will strengthen a crystal more than a hard one

  16. Particle Hardening • Three types of interphase boundaries: coherent (or ordered), fully disordered, intermediate type (partially ordered) • Several factors are involved: particle size, volume fraction, particle shape, the interfacial condition (bonding strength) between the particle and the matrix.

  17. Distorted Structure due to Incoherent Precipitates

  18. Interaction between Particles and Matrix • Coherency hardening will develop internal lattice strain due to different volume ratios (particle and matrix) • coh=(ap –am)/am • rf/b is the strengthening factor • When the particle parameter is greater than the matrix parameter, the particle is under compression.

  19. Dislocations Form Loops around Strong Particles

  20. Edge Dislocation Moving through An Ordered Particle Arrangement • Antiphase boundary Energy (APBE)

  21. Summary • Effective obstacle spacing (L’) and the angle (c) between two bent lines • For weak obstacles, dislocations bend slightly before passing through them. • For strong obstacles, dislocations loop around them. • Dislocations can’t pass through grain boundaries and large incoherent particles. Strengthening effects are produced. • Strengthening effects in aggregates go by volume fractions.

  22. Hardening Mechanisms in Crystals

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