1. Basics of structural crystalography
1.1. Periodical structures
1.2. Graitings and bond
2. Defects in crystals
2.1. Ideal and real crystal
2.2. Points defects, concentration, observation methods
2.3. Dislocations in important structures
2.4. Experimental methods
3. Structural analysis
3.1. X-ray analysis and Bragg equation
3.2. Theory of difraction
3.3. Atomic and structural factors
3.4. Neutron and electron difraction, using in practise
4. Deformation of single crystals of pure metals
4.1. Elastic and plastic deformation
4.2. Geometry of deformation
4.3. Hardening curve
4.4. Influence of orietnation, temperature, velocity
5. Alloys deformation
5.1. Interaction between dislocation and admixtures
5.2. Glide stress in high temperature range (Portevin -LeChatelier effect, etc.)
5.3. Precipitation hardening
6. Polycrystal deformation
6.1. Deformation proofs
6.2. Recovery and recrystalisation
6.3. Superplasticity
6.4. Twinnigs
1.1. Periodical structures
1.2. Graitings and bond
2. Defects in crystals
2.1. Ideal and real crystal
2.2. Points defects, concentration, observation methods
2.3. Dislocations in important structures
2.4. Experimental methods
3. Structural analysis
3.1. X-ray analysis and Bragg equation
3.2. Theory of difraction
3.3. Atomic and structural factors
3.4. Neutron and electron difraction, using in practise
4. Deformation of single crystals of pure metals
4.1. Elastic and plastic deformation
4.2. Geometry of deformation
4.3. Hardening curve
4.4. Influence of orietnation, temperature, velocity
5. Alloys deformation
5.1. Interaction between dislocation and admixtures
5.2. Glide stress in high temperature range (Portevin -LeChatelier effect, etc.)
5.3. Precipitation hardening
6. Polycrystal deformation
6.1. Deformation proofs
6.2. Recovery and recrystalisation
6.3. Superplasticity
6.4. Twinnigs