Education Information System

Course Information

FIZ726 - Güneş Pilleri Aygıt Fiziği ve Üretim Teknolojisi

Rapor Tarihi: 24.02.2026 10:24

Course Information

Course Title	Code	Language	Type	Semester	L+U Hour	Credits	ECTS
Device Physics Of Solar Cells And Production Technology	FIZ726	Turkish	Compulsory		3 + 0	3.0	7.5

Prerequisite Courses
Course Level	Graduate
Mode of delivery	Lecturing
Course Coordinator	Prof. Dr. Muharrem GÖKÇEN
Instructor(s)
Goals	Renewable source of energy, giving basic information about the Sun. Physics of solar cells, explaining the working principle and production techniques in detail.
Course Content	Renewable energy sources,Solar energy, the spectrum of sunlight,Structure of solar cells; Operation principle, characteristics and parameters,Structure of solar cells; Operation principle, characteristics and parameters,Developments principles of solar cell systems,Electronic of solar cell systems, DC/DC and AC/DC inverters,Solar battery supply circuits and lighting systems,Solar battery-powered battery charging systems,Semiconductor solar cells,Organic and inorganic solar cells,Single crystal growth techniques,Mechanism and dynamics of growth,Thin film growth techniques,Epitaxy growth techniques.

Learning Outcomes

#	Öğrenme Kazanımı
0	Structure of solar cells, their operation principles, characteristics and parameters will be comprehended, and various techniques for fabrication of solar cells will be learned.

Lesson Plan (Weekly Topics)

Week	Topics/Applications	Method
1. Week	Renewable energy sources.	Interview, Presentation (Preparation)
2. Week	Solar energy, the spectrum of sunlight.	Interview, Presentation (Preparation)
3. Week	Structure of solar cells; Operation principle, characteristics and parameters.	Interview, Presentation (Preparation)
4. Week	Structure of solar cells; Operation principle, characteristics and parameters.	Interview, Presentation (Preparation)
5. Week	Developments principles of solar cell systems.	Interview, Presentation (Preparation)
6. Week	Electronic of solar cell systems, DC/DC and AC/DC inverters.	Interview, Presentation (Preparation)
7. Week	Solar battery supply circuits and lighting systems.	Interview, Presentation (Preparation)
8. Week	Solar battery-powered battery charging systems
9. Week	Solar battery-powered battery charging systems.	Interview, Presentation (Preparation)
10. Week	Semiconductor solar cells.	Interview, Presentation (Preparation)
11. Week	Organic and inorganic solar cells.	Interview, Presentation (Preparation)
12. Week	Single crystal growth techniques.	Interview, Presentation (Preparation)
13. Week	Mechanism and dynamics of growth.	Interview, Presentation (Preparation)
14. Week	Thin film growth techniques.	Interview, Presentation (Preparation)

*Midterm and final exam dates are not specified in the 14-week course operation plan. Midterm and final exam dates are held on the dates specified in the academic calendar with the decision of the University Senate.

The Matrix for Course & Program Learning Outcomes

No	Program Requirements	Level of Contribution
No	Program Requirements	1	2	3	4	5
1	Improving the basic of theoretical and experimental applications of Classical, Modern and Quantum Physics knowledge obtained through undergraduate education to advanced level.					✔
2	Interpreting the encountered physical problems of advanced level according to physical principles and improving the ability of solving such problems.				✔
3	Obtaining the ability of setting connection between theory and applications about physics.					✔
4	Following and interpreting physics literature and obtaining the ability of preparing advanced pulications using these acqusitions.					✔
5	Gaining the ability of presenting in front of a community with the help of the acqusition through the courses taken during graduate education.				✔
6	Using the background and approaches of different principles at a level of producing new theorems.					✔
7	Obtaining the ability of gathering information, making comparisons, analizing and generating solution to the problems of experimental or theoretical physics.					✔
8	Gaining the ability of following and using the physics literature which progresses daily through contacting with colleagues working on similar subjects at the attended activities such as workshop, seminar and conference.				✔
9	Setting a theoretical model, solving the problems related to that model, approaching experimentally to the model, making the analysis of the experimentally obtained data and interpreting it through the advanced level knowledge obtained through graduate education.					✔
10	Ensuring the constitution of all information that will be used along with the academical life at advanced level and reaching to the level that advanced level researches about physics can be conducted by defining the relationship between the obtained knowledge.				✔

Relations with Education Attainment Program Course Competencies

Program Requirements	DK1
PY1	5
PY2	4
PY3	5
PY4	5
PY5	4
PY6	5
PY7	5
PY8	4
PY9	5
PY10	4

Recommended Sources

Ders Kitabı veya Notu	Ders Kitabı veya Ders Notu bulunmamaktadır.
Diğer Kaynaklar	• J. Nelson, The Physics of Solar Cells (Properties of Semiconductor Materials), Imperial College Press, 2003. • P. Würfel, Physics of Solar Cells: From Basic Principles to Advanced Concepts, 2 Upd Exp Edition, Wiley-VCH, 2009. • S.R. Wenham, M.A. Green, M.E. Watt, R. Corkish, Applied Photovoltaics, 2nd Edition, Earthscan Publications Ltd., 2007. • J. Poortmans, V. Arkhipov, Thin Film Solar Cells: Fabrication, Characterization and Applications, Wiley, 2006. • A. Luque, S. Heqedus, Handbook of Photovoltaic Science and Engineering, 2nd Edition, Wiley,2011

ECTS credits and course workload

ECTS credits and course workload		Quantity	Duration (Hour)	Total Workload (Hour)
Ders İçi	Class Hours	14	3	42
Ders Dışı	Preparation, After Class Study	14	2	28
	Research	14	3	42
	Other Activities	14	3	42
Sınavlar	Midterm 1	1	2	2
	Homework 1	14	2.5	35
	Final	1	2	2
Total Workload				193
*AKTS = (Total Workload) / 25,5		ECTS Credit of the Course		25.5 7.5