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Course Description Course Name : Retrosynthetic Analysis Course Code : KM 444 Course Type : Optional Level of Course : First Cycle Year of Study : 4 Course Semester : Spring (16 Weeks) ECTS : 4 Name of Lecturer(s) : Prof.Dr. ELİFE SULTAN VAYISOĞLU GİRAY Learning Outcomes of the Course : learn how a complex compound synthesed from starting materials Mode of Delivery : Face-to-Face Prerequisites and Co-Prerequisites : None Recommended Optional Programme Components : None Aim(s) of Course : application of reaction mechanizm Course Contents : synthesis of target molecules Language of Instruction : Turkish Work Place : class room   Course Outline /Schedule (Weekly) Planned Learning Activities Week Subject Student's Preliminary Work Learning Activities and Teaching Methods 1 introduction study on books slayt show 2 Retrosynthetic analysis 1: basic principles study on books slayt show 3 Retrosynthetic analysis II: latent polarity, functionel group conversion study on books slayt show 4 Retrosynthetic analysis II: latent polarity, functionel group conversion study on books slayt show 5 C-C bond formation reactions study on books slayt show 6 C-X bond breaking reactions study on books slayt show 7 bond breaking in 1,2-1,3- difunctional groups study on books slayt show 8 mid term exam study on books written exam 9 bond breaking of alcohols study on books slayt show 10 aryl ketones study on books slayt show 11 a-dicarbonyl compounds study on books slayt show 12 homeworks study on books oral presentation 13 homeworks study on books oral presentation 14 homeworks study on books oral presentation 15 homeworks study on books oral presentation   Required Course Resources Resource Type Resource Name Recommended Course Material(s)  organic synthesis - Willis and Wills Required Course Material(s)   Assessment Methods and Assessment Criteria Semester/Year Assessments Number Contribution Percentage     Mid-term Exams (Written, Oral, etc.) 1 50     Homeworks/Projects/Others 5 50 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 Feel comfortable with chemistry knowledge and capable to make relation with practical applicaitons 4 2 Observe and analyze the developments, directions and needs of industires for sustainability 4 3 Acquire life long education capability 4 4 Have capability of reaching for information 3 5 Acknowledge about total quality and relating the knowledge from different disciplines 3 6 Have capability of evaluating the national sources for technology development 4 7 Have capability of transmitting the knowledge and relating different disciplines 3 8 Gain the ability to achieve new knowledge and technology 5 9 Learn problem solving methodolygy and creative thinking 4 10 Have capability of bringing together theory and practical applicaiton 4 11 Feel comfortable with laboratory studies 0 12 Follow the developments in chemistry industries 0 13 Monitor progress in the field of chemistry. 4 14 Have capability of team work and leadership 4 15 Acquire property of objective and critical view 4 * 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) 13 2 26     Out of Class Study (Preliminary Work, Practice) 14 2 28 Assesment Related Works     Homeworks, Projects, Others 5 2 10     Mid-term Exams (Written, Oral, etc.) 1 10 10     Final Exam 1 20 20 Total Workload: 94 Total Workload / 25 (h): 3.76 ECTS Credit: 4