Individual course details
Study programme			Theoretical and experimental physics
Chosen research area (module)
Nature and level of studies
Name of the course			Quantum mechanics 1
Professor (lectures)			Milan Damnjanović
Professor/associate (examples/practical)			Marko Milivojević
Professor/associate (additional)
ECTS		6	Status (required/elective)	required
Access requirements	Mathematical physics 1, Theoretical mechanics
Aims of the course	Clarification of the principles of quantum physics and basic diffrences with respect to classical one, elementary techniques
Learning outcomes	Quantum knematics, basic quantum dynamics, Schrodinger equation and solutions of the most important problems.
Contents of the course
Lectures	1. Quantum kinematics: states, superposition. 2. Obsevables, measurements, correlations. 3. Uncertainty relations. 4. Quantization. 5. Schrodinger's, Heisenberg's and Dirac's picture. 6.Dynamics: evolution, Schrodinger equation (time dependentnt and time independent). 7.Evolution of the mixed states, averages, uncertainty relation energy-time. 8. Elementary dynamical problems: picewise constant potentials. 9. Harmonic oscilaor. 10. Approxmate methods 1.: time independent perturbations. 11. Variational method. 12. Adiabatic approximation. 13. Quantization of the Galileo's group. 14. Rotations and angular momentum. 15. Hydrogen atom. 16. Spin
Examples/ practical classes	Exercises, discussions, seminars, homeworks.
Recommended books
1	C. Cohen-Tannoudji, B. Diu, F. Laloe, Quantum Mechanics, (J. Wiley & Sons, New York, 1977)
2	М. Damnjanovic, Lecture notes
3	L.D. Landau, E.M. Lifshitz,"Quantum Mechanics" (Pergamon: Oxford 1977)
4
5
Number of classes (weekly)
Lectures	Examples&practicals		Student project	Additional
3	2
Teaching and learning methods
Assessment (maximal 100)
assesed coursework		mark	examination	mark
coursework		10	written examination	50
practicals			oral examination	40
papers
presentations