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This course teaches the basic principles of molecular and chemical physics which are essential for building and understanding experiments in molecular, physical and analytical chemistry. This two-term course is divided into 4 topics: Optical methods, mass spectrometry, molecular beams, and surface scanning techniques. Particular examples can be tunneling electron microscopy, atom force microscopy, ion traps, quadrupol and higher multipole analyzers, multiphoton spectroscopies and resonance methods, molecular beams, electron litography, interference resonators etc. Corresponding theory of these experimental approaches will be introduced.
Last update: Pátková Vlasta (05.01.2018)
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R: Demtröder, W., Molecular Physics, Wiley-VCH; 1 edition (December 2, 2005), ISBN-10: 3527405666 R: Townes Ch., Schawlow A.L., Microwave spectroscopy, Dover Publications, 2nd edition (July 17, 2012), ISBN-10: 048661798X R: Demtröder, W., Laser spectroscopy - experimental techniques, Springer; 4th edition (September 17, 2008), ISBN-10: 3540749527 A: G. Scoles, Atomic and Molecular Beam Methods: Volume 1, Oxford University Press, USA (November 24, 1988), ISBN-10: 0195042808 A: G. Scoles, Atomic and Molecular Beam Methods, Volume 2, vol. 2. Oxford: Oxford University Press, 1992. A: H. Pauly, Atom Molecule and Cluster Beams I. Basic Theory, Production, and Detection of Thermal Energy Beams. Berlin, Heidelberg, New York, Barcelona, Hong Kong, London, Milan, Paris, Singapore, Tokyo: Springer, 2000 A: H. Pauly, Atom, Molecule, and Cluster Beams II: Cluster Beams, Fast and Slow Beams, Accessory Equipment and Applications. Springer, 2000 A: F. J. Duarte, Tunable Lasers Handbook. Academic Press, 1995 Last update: Pátková Vlasta (05.01.2018)
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1. Introduction, history and overview of the corresponding techniques and basic principles 2. Basic theory of molecule-radiation interaction, overview of the techniques 3. Non-coherent light sources, characteristics, overview, usage 4. Coherent light sources, lasers: theory and instrumentation 5. Spectroscopy: various methods and instrumentation 6. Special spectroscopic methods 1: high-sensitivity direct absorption methods, CRDS, CEAS 7. Special spectroscopic methods 2: multiphoton methods LIF, REMPI 8. Microwave and THz spectroscopy: basic principles and instrumentation 9. Microwave and THz spectroscopy: special techniques 10. History and method overview 11. Mass spectrometers and their application 12. Special methods of mass spectrometry 1: SIFT-MS, ion traps 13. Special methods of mass spectrometry 2: electrospray, biomolecular applications 14. Special methods of mass spectrometry 3: ion imaging Last update: Pátková Vlasta (05.01.2018)
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http://www.jh-inst.cas.cz/~farnik/#home.htm Last update: Pátková Vlasta (05.01.2018)
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The knowledge and skills gained by the student: Ability to design experimental setups for study of chemistry at the molecular level, understand and apply laser-based technologies, microwave technologies, scanning microscope techniques; understand the principles of ion detection, cavity ring-down-spectroscopy, ICLAS; design various resonators; understand molecular beam principles, adiabatic cooling; ability to apply different signal processing methods; ability to interpret the experiments in terms of basic quantum mechanics. Last update: Pátková Vlasta (05.01.2018)
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Molecular Physical Chemistry and Symetry Molecular Spectroscopy Last update: Pátková Vlasta (05.01.2018)
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Teaching methods | ||||
Activity | Credits | Hours | ||
Účast na přednáškách | 1 | 28 | ||
Příprava na zkoušku a její absolvování | 2 | 56 | ||
3 / 3 | 84 / 84 |
Coursework assessment | |
Form | Significance |
Examination test | 40 |
Oral examination | 60 |