Laboratory of Molecular Spectroscopy

General data

Course ID:	1200-1ENSPMOLL4
Erasmus code / ISCED:	13.3 Kod klasyfikacyjny przedmiotu składa się z trzech do pięciu cyfr, przy czym trzy pierwsze oznaczają klasyfikację dziedziny wg. Listy kodów dziedzin obowiązującej w programie Socrates/Erasmus, czwarta (dotąd na ogół 0) – ewentualne uszczegółowienie informacji o dyscyplinie, piąta – stopień zaawansowania przedmiotu ustalony na podstawie roku studiów, dla którego przedmiot jest przeznaczony. / (0531) Chemistry The ISCED (International Standard Classification of Education) code has been designed by UNESCO.
Course title:	Laboratory of Molecular Spectroscopy
Name in Polish:	Spektroskopia molekularna - laboratorium
Organizational unit:	Faculty of Chemistry
Course groups:
ECTS credit allocation (and other scores):	(not available) Basic information on ECTS credits allocation principles: the annual hourly workload of the student’s work required to achieve the expected learning outcomes for a given stage is 1500-1800h, corresponding to 60 ECTS; the student’s weekly hourly workload is 45 h; 1 ECTS point corresponds to 25-30 hours of student work needed to achieve the assumed learning outcomes; weekly student workload necessary to achieve the assumed learning outcomes allows to obtain 1.5 ECTS; work required to pass the course, which has been assigned 3 ECTS, constitutes 10% of the semester student load. view allocation of credits
Language:	Polish
Type of course:	obligatory courses
Prerequisites (description):	It is assumed that a student has knowledge of quantum chemistry and molecular spectroscopy at the level of Quantum mechanics and quantum chemistry with introduction to molecular spectroscopy for the 2nd year of bachelor studies in chemistry at the Faculty of Chemistry, University of Warsaw.
Short description:	Laboratory exercises in molecular spectroscopy: UV/VIS, IR, Raman, NMR.
Full description:	The course consists of five laboratory exercises, during which a student gets familiar with the spectroscopic methods which are most often applied in chemistry. The exercises are aimed at demonstration of practical applications of methods presented during the lecture, and at extending the theoretical knowledge. UV VIS - The influence of substituents on the electronic spectra of benzene derivatives. IR - Investigation of hydrogen bonds by means of infra red spectroscopic methods. R - Analysis of the mixture of xylenes on the basis of their Raman spectrum. NMR - Interpretation of simple NMR spectra.
Bibliography:	1.Peter William Atkins, Physic Chemistry, Wydawnictwo Naukowe PWN, W-wa 2003. 2. J. Michael Hollas, Modern Spectroscopy, John Wiley & Sons; http://optdesign.narod.ru/book/Hollas_Modern_spectroscopy.pdf 3. Peter F.Bernoth, Spectra of atoms and Molecules, Oxford University Press, 1995 2. Engel T., Quantum Chemistry and Spectroscopy, Pearson, 2006
Learning outcomes:	A student should be able to carry out a basic interpretation of spectra and know the applications of the most important spectroscopic methods in chemistry
Assessment methods and assessment criteria:	The grade is an average of partial grades from four laboratory exercises, graded on the basis of intruductory test and lab report.
Practical placement:	Does not concern.

This course is not currently offered.

Course descriptions are protected by copyright.
Copyright by University of Warsaw.