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Consultation through MS Teams.
Solid State Physics
| Type of study | Bachelor |
|---|---|
| Language of instruction | Czech |
| Code | 480-2061/01 |
| Abbreviation | FPL |
| Course title | Solid State Physics |
| Credits | 4 |
| Coordinating department | Department of Physics |
| Course coordinator | prof. Dr. RNDr. Jiří Luňáček |
Subject syllabus
1. Crystal structure
1.1. Periodical structures, symetry
1.2. Simple crystal structures
2. Crystal difraction and reciprocial graiting
2.1. Bragg equation
2.2. Experimental difraction methods
2.3. Brilloin zones a nd reciprocial graitings
2.4. Atomic and structural factor
3. Crystal bond
3.1. Ionic and covalent bonds and crystals
3.2. Graiting constants
3.3. Ionic, covalent and metalic crystals
4. Fundamentals of electronic structure of solids
4.1. Pauli exclusion principle, valence electrons
4.2. Energy levels of atoms versus energy bands in crystals
4.3. Energy bands in metals, semiconductors and insulators - connections with
electrical properties – examples.
5. Heat properties of graiting
5.1. Heat vibration of graiting
5.2. Heat expansivity and conductivity
5.3. Fermi energy and electron specific heat
6. Point defects
6.1. Types oif point defects
6.2. Concentration of point defects and diffusion
7. Dislocations
7.1. Basic types of dislocations
7.2. Burgers vector
7.3. Sources and motion fo dislocations
7.4. Experimental observation methods
8. Elastic and plastic deformation of crystals
8.1. Deformation of pure metals
8.2. Curve of hardening
8.3. Critical stress
8.4. Hardening in important crystal structures (f.c.c., h.c.p., b.c.c.)
1.1. Periodical structures, symetry
1.2. Simple crystal structures
2. Crystal difraction and reciprocial graiting
2.1. Bragg equation
2.2. Experimental difraction methods
2.3. Brilloin zones a nd reciprocial graitings
2.4. Atomic and structural factor
3. Crystal bond
3.1. Ionic and covalent bonds and crystals
3.2. Graiting constants
3.3. Ionic, covalent and metalic crystals
4. Fundamentals of electronic structure of solids
4.1. Pauli exclusion principle, valence electrons
4.2. Energy levels of atoms versus energy bands in crystals
4.3. Energy bands in metals, semiconductors and insulators - connections with
electrical properties – examples.
5. Heat properties of graiting
5.1. Heat vibration of graiting
5.2. Heat expansivity and conductivity
5.3. Fermi energy and electron specific heat
6. Point defects
6.1. Types oif point defects
6.2. Concentration of point defects and diffusion
7. Dislocations
7.1. Basic types of dislocations
7.2. Burgers vector
7.3. Sources and motion fo dislocations
7.4. Experimental observation methods
8. Elastic and plastic deformation of crystals
8.1. Deformation of pure metals
8.2. Curve of hardening
8.3. Critical stress
8.4. Hardening in important crystal structures (f.c.c., h.c.p., b.c.c.)
E-learning
Literature
Haasen, O.: Physical Metallurgy, Cambridge University Press, third edition,
Cambridge 1996, ISBN 0 521 55092 0.
Kittel, Ch.: Introductions to Solid State Physics, John Wiley and Sons, first
edition, Cambridge 1953, (and next).
Cambridge 1996, ISBN 0 521 55092 0.
Kittel, Ch.: Introductions to Solid State Physics, John Wiley and Sons, first
edition, Cambridge 1953, (and next).
Advised literature
Haasen, P.: Physical Metallurgy, Cambridge University Press, third edition,
Cohen, M.L. and Louie, S.G.: Fundamentals of Condensed Matter Physics, Cambridge University Press, 2017.
Cohen, M.L. and Louie, S.G.: Fundamentals of Condensed Matter Physics, Cambridge University Press, 2017.