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Advanced Quantum Mechanics for chemical physics and sensorics - P403021

Title:	Pokročilá kvantová mechanika pro chemickou fyziku a senzoriku
Guaranteed by:	Department of Physical Chemistry (403)
Faculty:	Faculty of Chemical Engineering
Actual:	from 2020
Semester:	both
Points:	0
E-Credits:	0
Examination process:
Hours per week, examination:	2/1, other [HT]
Capacity:	winter:unlimited / unlimited (unknown) summer:unknown / unknown (unknown)
Min. number of students:	unlimited
Qualifications:
State of the course:	taught
Language:	Czech
Teaching methods:	full-time
Level:
Note:	course is intended for doctoral students only can be fulfilled in the future you can enroll for the course in winter and in summer semester

Guarantor:	Slavíček Petr prof. RNDr. Bc. Ph.D. Kolafa Jiří prof. RNDr. CSc. Kolář Michal doc. RNDr. Ph.D.
Is interchangeable with:	AP403021

Examination dates

This subject contains the following additional online materials

E-learning course

Annotation -

The course dedicated to Ph.D. students covers more advanced parts of quantum theory which are typically not treated in details within usual chemical curriculum.

Last update: Matějka Pavel (16.06.2019)

Course completion requirements -

The course ends with an oral exam.Individual project focusing on a certain sub=project is part of the course.

Last update: Slavíček Petr (13.11.2018)

Literature -

Z: E. Bittner: Quantum dynamics: applications in biological and materials systems. CRC press, 2009, 1420080539.

Z: P. W. Atkins, R. R. Friedman: Molecular Quantum Mechanics, Oxford University Press, Oxford 2010, 0199541426.

Last update: Slavíček Petr (13.11.2018)

Teaching methods - Czech

Přednášky a cvičení.

Last update: Slavíček Petr (13.11.2018)

Syllabus -

1. Experimental foundations of quantum mechanics.

2. Postulates of quantum mechanics I: Probability amplitude, superposition principle.

3. Postulates of quantum mechanics II: Mean value, measurables, operators.

4. Postulates of quantum mechanics III: Time evolution.

5. Operator methods in quantum mechanics I: harmonic oscillator, annihilation and creation operator.

6. Operator methods in quantum mechanics I: angular momentum, ladder operators.

7. Perturbation theory: Derivation and applications.

8. Perturbation theory: van der Waals interaction in various perspectives.

9. Time-dependent perturbation theory: constant and harmonic perturbation. Rabi oscillations.

10. Vibrational, rotational, atomic and molecular spectra. Selection rules. Franck-Condon principle.

11. Excitation transfer. Multi-photon processes and perturbation theory of higher orders.

12. Interaction of light and molecules. Spectral lineshapes. Einstein coefficients.

13. Time-dependent approach to spectroscopy. Autocorrelation function.

14. Elements of scattering theory. Green functions.

Last update: Slavíček Petr (13.11.2018)

Learning resources -

http://www.vscht.cz/fch/cz/vyuka/N403007.html

Last update: Slavíček Petr (13.11.2018)

Learning outcomes -

The student will be able to:

understand formalism of quantum theory

actively follow primary literature in theoretical chemistry

analyze molecular experiments in time and energy domains

Last update: Matějka Pavel (13.11.2018)

Registration requirements

Mathematics I, Physics I

Last update: Slavíček Petr (13.11.2018)