Course Information


Course Information
Course Title Code Semester L+U Hour Credits ECTS
PHYSICAL CHEMISTRY II CHM0216 4. Semester 4 + 0 4.0 5.0

Prerequisites None

Language of Instruction English
Course Level Bachelor's Degree
Course Type Compulsory
Mode of delivery
Course Coordinator
Instructors
Assistants
Goals Understanding the electrochemical reaction kinetics, conductivity and it's applications, battery and battery types, electrolyses, corrosion, mechanism of reactions, reaction rates and factors that affecting to reaction rates.
Course Content Rubber, the basic raw material used very frequently in daily life, rubber processing and recovery technologies
Learning Outcomes 1) 1) The student makes a correlation between chemical energy and electrical enery in electrochemical reactions.
2) 2) The student explains the conductivity, resistance and current properties of solutions.
3) 3) The student recognizes to occur a battery and acumulator and their usage areas.
4) 4) The student compares the classic and renewable batteries.
5) 5) The student compares the similarities and diversities of electrolysis and battery.
6) 6) The student examines the factors that affect reaction mechanism and rate.

Weekly Topics (Content)
Week Topics Teaching and Learning Methods and Techniques Study Materials
1. Week Electrical concepts, static electric , Coulomb law, electric area and electrical potential Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
2. Week Electrical terms: Faraday laws. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
3. Week Thermodynamics of electrolyte solutions: Thermodynamic properties of ions and activity. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
4. Week Ionic equilibrium: Debye-Hückel law and average activity coefficient. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
5. Week Electrolytic conductivity: Measuring the conductivity and conductivity applications. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
6. Week Electrolytic conductivity: Determining the transport numbers. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
7. Week Electrochemical cells: Electrot potantial and measuring electrot potantial. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
8. Week Electrochemical cells: Electrot potantial and measuring electrot potantial. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
9. Week Electrochemical cells: electrolysis and its applications. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
10. Week Chemical kinetics: Reaction rate laws. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
11. Week Chemical kinetics: Reaction rate laws. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
12. Week Chemical kinetics: Kinetics of complex reactions. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
13. Week Chemical kinetics: Some complex reactions. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)
14. Week Catalyze: Homogene, heterogene and enzyme catalyze. Lecture; Question Answer; Discussion; Case Study

Presentation (Including Preparation Time)

Sources Used in This Course
Recommended Sources
"Y. Sarıkaya, Fizikokimya, 1997, Gazi kitabevi, Ankara. "
P.W. Atkins, Physical Chemistry, Çeviri Editörleri: S. Yıldız, H. Yılmaz, E. Kılıç, 1998, Oxford University Press.

Relations with Education Attainment Program Course Competencies
Program RequirementsContribution LevelDK1DK2DK3DK4DK5DK6
PY15000000
PY25000000
PY35000000
PY45000000
PY55000000

*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) 14 4
Work Hour outside Classroom (Preparation, strengthening) 14 2
Midterm Exam 2 1.5
Time to prepare for Midterm Exam 2 15
Final Exam 1 1.5
Time to prepare for Final Exam 1 20
Total Workload
Total Workload / 30 (s)
ECTS Credit of the Course
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Course Information