SubjectsSubjects(version: 965)
Course, academic year 2019/2020
  
Advanced Methods of Chemical Physics I - AP402012
Title: Advanced Methods of Chemical Physics I
Guaranteed by: Department of Analytical Chemistry (402)
Faculty: Faculty of Chemical Engineering
Actual: from 2019
Semester: summer
Points: summer s.:0
E-Credits: summer s.:0
Examination process: summer s.:
Hours per week, examination: summer s.:2/1, other [HT]
Capacity: unlimited / unlimited (unknown)
Min. number of students: unlimited
State of the course: taught
Language: English
Teaching methods: full-time
Level:  
Note: course is intended for doctoral students only
can be fulfilled in the future
Guarantor: Fárník Michal doc. Mgr. Ph.D., DSc.
Votava Ondřej Mgr. Ph.D.
Urban Štěpán prof. RNDr. CSc.
Classification: Chemistry > Physical Chemistry
Interchangeability : P402012
Examination dates   Schedule   
Annotation -
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:, 1) molecular beam; 2) mass spectrometry, 3) lasers and optical methods; 4)surface scanning techniques. In the first part, underlying physical principles of these methods will be introduced, and in the second part, examples of modern experiments based on the above techniques will be reviewed. Particular examples of the topics introduced in this first part are: molecular beam techniques; basic principles of mass analyzers, magnetic and electric sector fields, time-of-flight spectrometers, quadrupoles etc.; theory and examples of lasers; tunneling electron and atom force microscopy.
Last update: Pátková Vlasta (16.11.2018)
Literature -

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:

Last update: Pátková Vlasta (16.11.2018)
Syllabus -

1. Introduction, history and overview of the corresponding techniques and basic principles

2. Basic principles of molecular beams, effusive and supersonic expansions

3. Basics of kinetic theory and fluid dynamics

4. Molecular and cluster beam characterization

5. Basic theory of molecule-radiation interaction, overview of the techniques

6. Lasers: theory and instrumentation, population inversion, resonators

7. Pulsed and continuous lasers

8. Laser examples: gas phase lasers, dye lasers, solid state lasers

9. Non-linear frequency mixing

10. Basic principles of mass spectrometry

11. Ionization methods: electron and photoionization, proton transfer, field ionization, electrospray, MALDI etc.

12. Ion trajectories in electric and magnetic fields

13. Sector fields, time-of-flight methods, quadrupoles and higher multipoles, ion traps

14. Charged particle detection

15. Microwave and THz spectroscopy: basic principles and instrumentation

16. Surface methods: tunneling electron and atom force microscopy

Last update: Pátková Vlasta (16.11.2018)
Learning resources -

http://www.jh-inst.cas.cz/dynamics/

Last update: Pátková Vlasta (16.11.2018)
Learning outcomes -

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, understand molecular beam principles, adiabatic cooling; ability to interpret the experiments in terms of basic quantum mechanics.

Last update: Pátková Vlasta (16.11.2018)
Entry requirements -

Molecular Physical Chemistry and Symetry, Molecular Spectroscopy

Last update: Pátková Vlasta (16.11.2018)
 
VŠCHT Praha