Simulation and Modeling In Materials Science
Metallurgical and Materials Engineering
Institute of Natural and Applied Sciences
Third Cycle (Doctorate Degree)
| Course Unit Title | Course Unit Code | Type of Course Unit | Level of Course Unit | Year of Study | Semester | ECTS Credits |
|---|---|---|---|---|---|---|
| Simulation and Modeling In Materials Science | MMT606 | Elective | Doctorate degree | 1 | Spring | 8 |
Name of Lecturer(s)
Associate Prof. Dr. Ersoy ERİŞİR
Assistant Prof. Dr. Gülşah AKTAŞ ÇELİK
Learning Outcomes of the Course Unit
1) Defining of simulation and modeling
2) performin of numerical simulation techniques
3) Performing of simulation of phase diagrams CALPHAD
4) Defining of basic principals of thermodynamic
5) Performing of thermodynamical modeling of phases and compounds
6) Defining of stablity of phases
7) Performing of crystal modeling and magnetic contribution to the Gibbs energy
8) Performing of simulation and modeling using of computers
9) Performing thermodynamical modeling-(ThermoCalc) on exemplary applications
10) Performing diffusion controlled transformations modeling (DICTRA) on exemplary applications
11) Performing thermodynamics and kinetics modeling on exemplary applications
Program Competencies-Learning Outcomes Relation
| Program Competencies | ||||
| 1 | 2 | 3 | ||
| Learning Outcomes | ||||
| 1 | No relation | Low | Low | |
| 2 | High | High | High | |
| 3 | High | High | High | |
| 4 | High | Low | Low | |
| 5 | High | High | High | |
| 6 | High | Low | Low | |
| 7 | High | Low | Low | |
| 8 | High | High | High | |
| 9 | High | High | High | |
| 10 | High | High | High | |
| 11 | High | High | High | |
Mode of Delivery
Face to Face
Prerequisites and Co-Requisites
None
Recommended Optional Programme Components
Not Required
Course Contents
Candidates are provided with in-depth knowledge on description of simulation and modeling, numerical simulation techniques, simulation of phase diagrams CALPHAD, basic principals of thermodynamic, thermodynamical modeling of phases and compounds, crystal modeling and magnetic contribution to the Gibbs energy, simulation and modeling using of computers, exemplary applications for thermodynamical modeling-ThermoCalc, examplary applications for diffusion controlled transformations- DICTRA, examplary applications for thermodynamics and kinetics.
Weekly Schedule
1) Introduction to simulation2) Basic principals of thermodynamic and kinetics about the programs
3) Basic principals of thermodynamic and kinetics about the programs
4) Numerical methods
5) Numerical methods
6) Using of the programs
7) Using of the programs
8) Exam
9) Using of the programs
10) Exemplary applications for solidification
11) Exemplary applications for solidification
12) Exemplary applications for diffusion controlled transformations
13) Exemplary applications for diffusion controlled transformations
14) Exemplary applications for diffusion controlled transformations
15) Exemplary applications for precipitation
16) Exam
Recommended or Required Reading
Planned Learning Activities and Teaching Methods
1) Lecture
2) Discussion
3) Demonstration
4) Group Study
5) Problem Solving
Assessment Methods and Criteria
Contribution of Midterm Examination to Course Grade |
40% |
|---|---|
Contribution of Final Examination to Course Grade |
60% |
Total |
100% |
Language of Instruction
Turkish
Work Placement(s)
Not Required