School of Engineering \ Material Science and Nanotechnology Engineering
Course Credit
ECTS Credit
Course Type
Instructional Language
Programs that can take the course
Can be taken as faculty elective course by the other engineering departments
Concept of State Function, Simple Equilibrium, Energy and Work Units, Intensive and Extensive Properties, Phase Diagrams and Thermodynamic Components, Kinetic Theory of Gases, Equations of State, Thermodynamic System, First and Second Laws of Thermodynamics, Reversible and Irreversible Processes, Thermodynamic Systems, Introduction to Basic Thermodynamic Cycles, Heat Capacity, Enthalpy, Entropy, Third Law of Thermodynamics, Statistical Entropy, Thermodynamic Properties of Solutions, Gases and Reactions.
Textbook and / or References
David R. Gaskell, Malzemelerin Termodinamiğine Giriş, Taylor & Francis, 2008.
This course includes a clear presentation of thermodynamic principles, concepts, and analysis methods to facilitate a better understanding of engineering thermodynamics. It also aims to integrate classical and statistical thermodynamics for engineering applications that require the derivation of fundamental equations and principles at a basic mathematical level.
1. Understanding the fundamental concepts of thermodynamics, such as system identification, intensive and extensive properties, differential equations for these variables, state functions, and equations of state.
2. Understanding reversible and irreversible processes within the concept of spontaneity.
3. Ability to apply the first law of thermodynamics.
4. Understanding the effects of work, heat, waste heat, and work on all thermodynamic processes.
5. Ability to apply the second law of thermodynamics and entropy concepts in analyzing the efficiency of heat engines using the Carnot cycle.
6. Ability to compare and contrast auxiliary functions such as enthalpy, internal energy, entropy, Helmholtz, and Gibbs free energy.
7. Ability to apply thermodynamic laws to processes such as adiabatic, isothermal, isochoric, and isobaric processes.
8. Ability to interpret thermodynamic laws using statistical thermodynamics.
9. Understanding phase equilibrium in a single-component system.
10. Ability to describe solid-solid, solid-liquid, and solid-gas equilibrium.
11. Understanding gas behavior through concepts such as deviations from ideality, gas mixtures, and partial molar properties.
12. Understanding solution behaviors within the framework of Raoult’s law, Gibbs-Duhem equations, and non-ideal concepts.
Week 1: Presentation and definition of terms such as process, equilibrium and system of units
Week 2: Energy and the first law of Thermodynamics, Energy of a system
Week 3: Energy transfer with heat and work, Energy balance for systems and cycles
Week 4: Reversible and Irreversible Processes
Week 5: Second Law of Thermodynamics
Week 6: Statistical Interpretation of Entropy
Week 7: Auxiliary Functions
Week 8: Heat Capacity, Enthalpy, Entropy
Week 9: Third Law of Thermodynamics
Week 10: Phase Equilibrium in a Single Component System
Week 11: Behavior of Gases
Week 12: Behavior of Solutions
Tentative Assesment Methods
Quiz: 25 %
Homework: 15 %
Midterms: 30 %
Final: 30 %
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