Organic Chemistry II 310-ERS-CHOR2E
Profile of studies: general academic
Form of studies: full-time
Type of subject: compulsory
Field: exact and natural sciences, discipline: chemical sciences
Year of studies/semester: year III, I/winter semester
Prerequisites: 310-ERS-CHOR1E
The number of teaching hours divided into forms of classes – 30 hours of lecture, 30 hours of seminar, 90 hours of laboratory
Didactic methods
Lecture: expository method (traditional lecture, interactive lecture with student engagement, problem-based approach), group work.
Seminar: expository method (problem-based approach), group work, individual work, brainstorming.
Laboratory: practical exercises, experiments, and observation.
ECTS points: 9
Student workload balance
Total student workload related to the class: 225.0 h (ECTS: 9.0)
Student workload related to activities requiring direct participation of a teacher: 153 h (ECTS: 6.1)
including:
1) attendance of lectures: 30.0 h (ECTS: 1.2)
2) participation in non-classroom activities: 120 h (ECTS: 4.8)
3) participation in consultations/assessments/examinations: 3.0 h (ECTS: 0.1)
Preparation for classes/assessments/examinations (student's own work): 72.0 h (ECTS: 2.9)
% hours of the student's own work: 32%
In addition, students are offered the opportunity to participate in consultations for 15 hours per semester.
Rodzaj przedmiotu
Założenia (lista przedmiotów)
Założenia (opisowo)
Koordynatorzy przedmiotu
Tryb prowadzenia przedmiotu
Efekty kształcenia
KNOWLEDGE:
The student knows and understands issues in the field of organic chemistry, enabling the discussion of the structure of organic compounds (including their spatial configuration) (KP6_WG1 and KP6_WG5), their physical and chemical properties (KP6_WG3), the explanation of reaction mechanisms (KP6_WG4), and the use of chemical terminology and nomenclature at an advanced level (KP6_WG2).
The student knows and understands the methods of synthesis, isolation, purification, and identification of organic compounds (KP6_WG7).
The student knows and understands issues in the field of health and safety, and in particular, knows the principles of the safe handling of chemicals and the selection and disposal of chemical waste (KP6_WG13).
SKILLS:
The student is able to identify and solve chemical problems based on acquired knowledge, including complex and atypical problems; plans and carries out experimental research (the student is able to plan and perform the synthesis of organic compounds, including multi-step syntheses) (KP6_UW1 and KP6_UW2), has mastered the manual skills necessary for laboratory work and is able to operate necessary laboratory equipment and scientific apparatus (KP6_UW3).
The student is able to observe experiments and draw conclusions from them, as well as prepare the results in written form (report) (KP6_UW4).
They are able to purify and identify organic compounds using classical and spectroscopic methods (KP6_UW2 and KP6_UW6).
The student adheres to the health and safety rules recommended in a laboratory environment (KP6_UO1). They are able to work in a group as well as independently (KP6_UU1).
SOCIAL COMPETENCES:
The student demonstrates an interest in chemical processes occurring in the environment (KP6_KO1).
Kryteria oceniania
Assessment and Evaluation
Lecture: The assessment consists of a final written exam on the lecture material. To be admitted to the exam, students must pass the laboratory and seminar components.
Seminar: Written tests. Systematic evaluation of work during the classes.
Laboratory:
(a) Preparation and practical work: Evaluation of practical skills, safe laboratory practices, and successful completion of experiments.
(b) Theoretical Understanding: Assessment via short written tests on the theory related to the experiments.
(c) Lab Reports: Timely submission and quality of written lab reports.
(d) Continuous Assessment: Systematic evaluation of preparation and engagement during all classes.
Assessment criteria based on the UwB regulations.
Flexible forms of assessment may be introduced through mutual agreement between the lecturer and student, following universal design principles. Such arrangements must be established at the beginning of the course.
Literatura
Literature:
(1) McMurry, J. E. (2015). Organic Chemistry (9th ed.). Cengage Learning.
(2) Bruice, P. Y. (2017). Organic Chemistry (8th ed.). Pearson.
(3) Clayden, J., Greeves, N., & Warren, S. (2012). Organic Chemistry (2nd ed.). Oxford University Press.
(4) Furniss, B. S., Hannaford, A. J., Smith, P. W. G., & Tatchell, A. R. (1996). Vogel's Textbook of Practical Organic Chemistry (5th ed.). Prentice Hall.
(5) Silverstein, R. M., Webster, F. X., & Kiemle, D. J. (2005). Spectrometric Identification of Organic Compounds (7th ed.). John Wiley & Sons.
Complementary literature:
(1) Smith, M. B., & March, J. (2001). March's Advanced Organic Chemistry: Reactions, Mechanisms, and Structure (5th ed.). Wiley-Interscience.
(2) Solomons, T. W. G., Fryhle, C. B., & Snyder, S. A. (2023). Organic chemistry (14th ed.). John Wiley & Sons.
(3) Mohrig, J. R., Hammond, C. N., & Schatz, P. F. (2010). Techniques in Organic Chemistry. W. H. Freeman.
Więcej informacji
Dodatkowe informacje (np. o kalendarzu rejestracji, prowadzących zajęcia, lokalizacji i terminach zajęć) mogą być dostępne w serwisie USOSweb: