Course Information


Course Information
Course Title Code Semester L+U Hour Credits ECTS
PHYSICAL CHEMISTRY III KİM0313 5. Semester 3 + 0 3.0 4.0

Prerequisites None

Language of Instruction English
Course Level Bachelor's Degree
Course Type Compulsory
Mode of delivery
Course Coordinator
Instructors Pınar ACAR BOZKURT
Assistants
Goals Application of physical methods on chemistry, quantity, volume, pressure and temperature as well as items that are large enough to be measured experimentally investigate macroscopic and comprehensive approach to give information, to develop the ability to think in physical chemistry.
Course Content Real Gases, Mixtures
Learning Outcomes 1) The student observes intermolecular interactions by experiments
2) The student defines the distinction between real and ideal gases and the the applicability of the real gas laws on real gases
3) The student defines chemical, physical and numerical properties
4) .The student searches the usability of the application of numeric properties
5) The student compares the partially miscible and immiscible liquids with each other

Weekly Topics (Content)
Week Topics Teaching and Learning Methods and Techniques Study Materials
1. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
2. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
3. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
4. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
5. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
6. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
7. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
8. Week Real gases: Intermolecular interactions, deviations from the ideal gas assumption, equations of state of real gases, real gases, liquids and solids, fixed internal energy event (Event Joule), the constant enthalpy (izentalpik) event (Event Joule Thomson), heat capacity, fugacity (effective pressure). Lecture; Question Answer; Discussion

 Homework
9. Week ixtures: Concentrations, partial molar properties, Gibbs phase rule, Nernst law of dispersion, solid-liquid and liquid-liquid equilibria, Henry, Raoult and Dalton Laws, liquid-gas equilibrium (absorption and desorption) Lecture; Question Answer; Discussion

 Homework
10. Week Mixtures: Concentrations, partial molar properties, Gibbs phase rule, Nernst law of dispersion, solid-liquid and liquid-liquid equilibria, Henry, Raoult and Dalton Laws, liquid-gas equilibrium (absorption and desorption) Lecture; Question Answer; Discussion

 Homework
11. Week ixtures: Concentrations, partial molar properties, Gibbs phase rule, Nernst law of dispersion, solid-liquid and liquid-liquid equilibria, Henry, Raoult and Dalton Laws, liquid-gas equilibrium (absorption and desorption) Lecture; Question Answer; Discussion

 Homework
12. Week liquid-vapor balance (distillation), solid-liquid balance: solubility and crystallization, numerical properties, non-electrolyte real mixtures, partial fugacity and partial fugacity coefficient, activity and activity coefficient, phase diagrams of partially mixed liquids, and phase diagrams of solid-solid equilibria. Lecture; Question Answer; Discussion

 Homework
13. Week liquid-vapor balance (distillation), solid-liquid balance: solubility and crystallization, numerical properties, non-electrolyte real mixtures, partial fugacity and partial fugacity coefficient, activity and activity coefficient, phase diagrams of partially mixed liquids, and phase diagrams of solid-solid equilibria. Lecture; Question Answer; Discussion

 Homework
14. Week liquid-vapor balance (distillation), solid-liquid balance: solubility and crystallization, numerical properties, non-electrolyte real mixtures, partial fugacity and partial fugacity coefficient, activity and activity coefficient, phase diagrams of partially mixed liquids, and phase diagrams of solid-solid equilibria. Lecture; Question Answer; Discussion

 Homework

Sources Used in This Course
Recommended Sources
Chemical and Engineering Thermodynamics; S.I.Sandler, Wiley, New York, 1989.
Explaining Activity Coefficientsand Standard States in the Undergraduate Physical Chemistry Course; A.Fanelli, J.Chem. Educ, 63, 112, 1986.
Fizikokimya; Y. Sarıkaya, Gazi Kitabevi, 2005.
Phase Equilibria; A.Reisman, Academic Press, Inc., New York, 1970.

Relations with Education Attainment Program Course Competencies
Program RequirementsContribution LevelDK1DK2DK3DK4DK5
PY1505000
PY2500000
PY3500000
PY4500000
PY5500000

*DK = Course's Contrubution.
0 1 2 3 4 5
Level of contribution None Very Low Low Fair High Very High
.

ECTS credits and course workload
Event Quantity Duration (Hour) Total Workload (Hour)
Course Duration (Total weeks*Hours per week) 16 3
Work Hour outside Classroom (Preparation, strengthening) 16 3
Midterm Exam 2 1.5
Time to prepare for Midterm Exam 2 10
Final Exam 1 1.5
Time to prepare for Final Exam 1 10
Total Workload
Total Workload / 30 (s)
ECTS Credit of the Course
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Course Information
  • Course Information
  • Weekly Topics (Content)
  • Sources Used in This Course
  • Relations with Education Attainment Program Course Competencies
  • ECTS credits and course workload