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Course Description Course Name : Photoelectric Properties of Semiconductors II Course Code : FK-610 Course Type : Optional Level of Course : Second Cycle Year of Study : 1 Course Semester : Spring (16 Weeks) ECTS : 6 Name of Lecturer(s) : Asst.Prof.Dr. ŞADİ YILMAZ Learning Outcomes of the Course : Elaborates on the terms about the photoelectric properties Uses the photoelectric properties to solve the problems Mode of Delivery : Face-to-Face Prerequisites and Co-Prerequisites : None Recommended Optional Programme Components : None Aim(s) of Course : It is aimed to help students understand the photoelectric properties in teorical and practical levels Course Contents : Thermoactive and photoactive spectroscopy terms in semiconductors, the band structure of semiconductors with luminescence data, band structure calculations, conductivity, mobility measurement techniques, irregular constructed matters (crystal, conductivity properties), the states of conduction and production of natural semiconductors in dopped semiconductors, Carier density calculation in natural and dopped semiconductors Language of Instruction : Turkish Work Place : Lecture hall of the Faculty   Course Outline /Schedule (Weekly) Planned Learning Activities Week Subject Student's Preliminary Work Learning Activities and Teaching Methods 1 Teaching the term of spectroscopy Research the related topic lecture, discussion 2 Thermoactive and photoactive spectroscopy terms in semiconductors Research the related topic lecture, discussion 3 Luminescence (photo - thermo) Research the related topic lecture, discussion 4 Obtaining the band structure of semiconductors from luminescence data Research the related topic lecture, discussion 5 Investigating of band structure calculations, conductivity, mobility measurement techniques Research the related topic lecture, discussion 6 Teaching irregular constructed matters (crystal, conductivity properties) Research the related topic lecture, discussion 7 Investigating band structure of semiconductors having irregular construction Research the related topic lecture, discussion 8 Midterm Exam Midterm Exam Midterm Exam 9 Continue to the 7th week Research the related topic lecture, discussion 10 Teaching the conditions of transitions from irregular structure to regular structure Research the related topic lecture, discussion 11 Giving the states of conduction and production of natural semiconductors in dopped semiconductors Research the related topic lecture, discussion 12 Calculations of carier density in natural semiconductors Research the related topic lecture, discussion 13 Calculations of carier density in dopped semiconductors Research the related topic lecture, discussion 14 n-p calculations Research the related topic lecture, discussion 15 Continue to the 14th week Research the related topic lecture, discussion 16/17 Final Final Final   Required Course Resources Resource Type Resource Name Recommended Course Material(s)  Electronic Properties of Crystalline Solids, Richard H. Bube.  Solid State Physics, H. Ibach & H. Lüth  Optical Properties of Solids, Frederich Wooten Required Course Material(s)   Assessment Methods and Assessment Criteria Semester/Year Assessments Number Contribution Percentage     Mid-term Exams (Written, Oral, etc.) 1 80     Homeworks/Projects/Others 1 20 Total 100 Rate of Semester/Year Assessments to Success 40   Final Assessments 100 Rate of Final Assessments to Success 60 Total 100   Contribution of the Course to Key Learning Outcomes # Key Learning Outcome Contribution* 1 Develop and deepen the knowledge as a specialist in physics or different areas based on the Physics Bachelor´s qualification level. 5 2 Comprehend the importance of multidisciplinary studies related to Physics. 5 3 Use his/her advanced theoretical and practical knowledge in Physics efficiently. 5 4 Integrate and interpret the knowledge from different disciplines with the help of his professional knowledge in Physics and conceptualize new perspectives. 5 5 Solve the problems in Physics by using research methods. 5 6 Carry out a study requiring expertise in physics independently. 5 7 Develop and provide new strategic approaches by taking responsibilty while solving the unexpected problems in Physics . 5 8 Take the responsibility of being the leader while solving the problems related to physical environments. 5 9 Evaluate the knowledge and skills gained in Physics by having a critical view and directs his/her learning. 5 10 Systematically transfer the current developments in the field of physics and his/her work to the person in physics field or outside of the field by supporting qualitative and quantitative data. 5 11 Take action to change the norms of social relations and critically examine these relationships, and develop them if necessary. 5 12 Make communication in oral and written by using at least one foreign language in the level of European Language Portfolio B2 level. 5 13 Use information and communication technologies in advanced level and use the software related with physics area. 5 14 Oversee social, scientific, cultural and ethical values in order to collect, implement, interpret data in Physics. 5 15 Develop strategies, policies and implementation plans in the issues related to the field of physics and evaluate the results obtained within the framework of quality processes. 5 16 Use the knowledge, problem solving, and / or practical skills obtained in the Physics Field in interdisciplinary studies. 5 * Contribution levels are between 0 (not) and 5 (maximum).   Student Workload - ECTS Works Number Time (Hour) Total Workload (Hour) Course Related Works     Class Time (Exam weeks are excluded) 14 3 42     Out of Class Study (Preliminary Work, Practice) 14 3 42 Assesment Related Works     Homeworks, Projects, Others 1 20 20     Mid-term Exams (Written, Oral, etc.) 1 20 20     Final Exam 1 20 20 Total Workload: 144 Total Workload / 25 (h): 5.76 ECTS Credit: 6