Course detail
Selected Chapters in Materials Science
FSI-9VFM Acad. year: 2023/2024 Winter semester
This course provides students with the theoretical foundations necessary for a complex solution of materials problems. It is conceived as the physical basis of processing technologies of metallic as well as nonmetallic structural metarials. It also includes physical-chemical fundamentals of the sythesis of materials and provides in-depth information about the deformation and fracture behaviour of materials, failure mechanisms, and fundamentals of fracture mechanics.
Language of instruction
Czech
Supervisor
Department
Entry knowledge
Fundamental knowledge of inorganic chemistry and physical chemistry, crystallography,and physics of solids. Fundamental notions from the field of thermodynamics. Fundamentals of materials science.
Rules for evaluation and completion of the course
Students sit an examination as part of their doctoral studies.
Students regularly attend lectures, recommended seminars and seminar consultations.
Aims
The objective is to make students familiar with the connections between the structure of real metallic and non-metallic crystals and the physical processes of their technological applications (heat treatment, metal forming, welding, casting).
This course enables students to acquire a knowledge about the internal structure of structural materials and about the thermodynamic and kinetic aspects of their phase transformations. Students are also made familiar with the deformation and fracture behaviour of materials, with the fundamentals of fracture mechanics, and with selected degradation processes (corrosion, wear).
The study programmes with the given course
Programme D-MAT-K: Materials Sciences, Doctoral, recommended course
Programme D-MAT-P: Materials Sciences, Doctoral, recommended course
Type of course unit
Lecture
20 hours, optionally
Syllabus
1. Chemical bonds in solids.
2. Structure of matter and lattice defects.
3. Vibrations of the crystal lattice.
4. Thermodynamics of phase transformation.
5. Diffusion in materials, mechanisms and quantitative descriptions.
6. Application of termodynamics, kinetics and diffusion in phase transformations.
7. Transformations controlled by diffusion.
8. Diffusionless transformations.
Extent and details consulted will depend on PhD topics and other PhD courses content.