Akademik Dersler - İçerik

1. Evaluate the importance of structural proporties in materials science and engineering.
1.1. It examines the “Structure”, “Properties”, “Processing” and “Performance” quartets.
1.2. Illustrate the structures of exemplary materials that came to prominence in their technology revolution.
1.3. Gives examples for structure-property-relationship and structure-performance-relationship in materials and evaluates the importance of structure.
2. will be able to explain the bonding types in materials and in the basic crystal structure.
2.1. Explain the bonding types in materials.
2.2. Defines the crystal structure (structure = lattice + motif).
2.3. Define two and three dimensional crystal systems, unit cells and Bravais lattices in metallic crystal systems.
2.4. Defines the atomic packaging ratio and calculates for metallic crystal systems.
2.5. Explain the FCC and HCP sequence.
2.6. Calculates theoretical and experimental density and atomic radius in crystal systems.
2.7. Explains and compares the basic properties of crystal, single crystalline, polycrystalline and amorphous materials; give examples for application areas.
2.8. Explain what is polymorphism.
2.9. Crystal lattice also defines point coordinates.
2.9. Defines point coordinates in crystal lattice.
3. will be able to explain crystal direction and planes and their properties in basic crystal structures.
3.1. Define, index and calculate linear densities of crystal systems.
3.2. Define the crystal planes in crystal systems, index and calculate their planar density.
3.3. Define the crystal directions and planes in the HCP crystal system, index and calculate density.
3.4. Can provide entry-level information on the X-ray diffraction technique for determination of crystal structure.
4. will be able to explain the properties of ceramic and oxide crystal structures.
4.1. Explain ceramic and oxide bond structures.
4.2. Define interstial sites, bond hybridization and ionic ratio, and calculate ionic ratio in ceramic and oxide crystal structures.
4.3. Explain, compare and calculate what is coordination number and ionic radius in crystal systems.
4.4. Can choose the interstial site in ceramic and oxide structures, make structure prediction for binary compounds.
4.5. Calculate density in ceramic structures, index crystal directions and planes.
4.6. Recognize different ceramic structures.
5. will be able to explain the basic symmetry properties of crystal systems.
5.1. Explain what is symmetry in crystal systems.
5.2. Define basic symmetry operations.
5.3. Identify and draw crystal symmetries in two-dimensional crystal systems and two-dimensional structures.
6. will be able to present and discuss the solutions of assignments.
6.1. Establish a team in the selected field of application and makes a literature review.
6.2. Prepares the solutions of the assignments given by team work.
6.3. By doing teamwork, investigates the application areas of the crystal structures in the given assignments and obtains an introductory idea in terms of material selection and design.
6.4. Presents the solutions prepared on the board during the application hours, and discusses with all students and faculty members.