Practical applications of spectroscopy 1200-2BLOK2-WYK1
Specifically, the course is intended to:
a) revisit and expand basic knowledge on qualitative and quantitative spectral analysis and spectral data processing,
b) introduce selected applications of molecular spectroscopy in identification of chemical compounds,
c) present a concrete range of research problems from the interface of clinical and environmental analysis, as well as material science and technology wherein spectroscopic methods are used.
The course will begin with a recollection of physical principles of the phenomena of absorption and emission of electromagnetic radiation by molecules. The following problems will be discussed in detail:
1) Basic approaches to chemometric spectra data processing including differentia spectra, deconvolution.
2) Problem-dependent selection of spectroscopic method.
3) UV / IR / Raman-spectroscopy-based identification of groups of chemical compounds.
4) Sensors and biosensors employing fluorescence and SERS
5) Identification of chemical compounds by NMR Spectroscopy methods
6) Determination of diffusion coefficients
7) Magnetic resonance imaging
Up to 5 absences is permitted.
Total student workload: 80 hours, consisting of:
1) Participation in classes: 30 hours
2) Preparation for classes and exams: 35 hours
3) Consultations with the lecturers: 15 hours
Prerequisites (description)
Course coordinators
Main fields of studies for MISMaP
Type of course
Learning outcomes
The goal of the course is to introduce students to practical applications of molecular spectroscopy (including both optical and nuclear-magnetic-resonance-based methods) in various fields of science, technology and medicine.
Codes of acquired knowledge and competences.: K_W01, K_W04, K_W06, K_W07, K_W08,, K_W10, K_U03, K_U04, K_U05, K_U06, K_U07, K_U08, K_U09, K_U10, K_U11, K_U13, K_U15, K_U17, K_K01, K_K02, K_K03, K_K04, K_K05
Assessment criteria
Final examination carried out in the oral form. Duration time is 30 minutes.
Bibliography
In Polish:
a) P. W. Atkins, Chemia Fizyczna, PWN, Warszawa, 2003.
b) Z. Kęcki, Podstawy spektroskopii molekularnej, PWN, Warszawa, 1992.
c) L. Stryer "Biochemia" PWN, Warszawa, 2003.
d) Biospektroskopia tomy 1-5 / pod red. Jacka Twardowskiego, Warszawa, PWN, 1989.
e) A. Ejchart, A. Gryff-Keller, „NMR w cieczach. Zarys teorii i metodologii”; Wydawnictwa Politechniki Warszawskiej, Warszawa 2003
In English:
a) Kensal E. van Holde, W. Curtis Johnson, P. Shing Ho Principles of physical biochemistry, Upper Saddle River, NJ, Pearson Education International, 2006. (Biblioteka Wydzialu Chemii UW)
b) Charles R Cantor, Paul R Schimmel Biophysical Chemistry Part I: The Conformation of Biological Macromolecules; Part II: Techniques for the Study of Biological Structure and Function; Part III: The Behavior of Biological Macromolecules, New York : W. H. Freeman and Company, 1980, 2001, 2002 (Biblioteka Wydzialu Chemii UW)
c) Donald T. Haynie Biological Thermodynamics Cambridge University Press, 2001.
d) SA Richards, JC Hollerton, Essential Practical NMR for organic chemistry, John Wiley and Sons, 2011
Additional information
Additional information (registration calendar, class conductors, localization and schedules of classes), might be available in the USOSweb system: