Course: Modern physics III

« Back
Course title Modern physics III
Course code KFY/MOF3
Organizational form of instruction Lecture + Lesson
Level of course Master
Year of study 3
Semester Summer
Number of ECTS credits 5
Language of instruction Czech
Status of course Compulsory-optional
Form of instruction unspecified
Work placements unspecified
Recommended optional programme components None
Lecturer(s)
  • Blažek Josef, doc. RNDr. CSc.
Course content
1) Quantum states description in Schrodinger´s representation Wave fiction and its statistical interpretation 2) Physical quantities in quantum theory I Matching operators to physical quantities, spectrums and medium values 3) Physical quantities in quantum theory Hermit operators properties, commensurability and non-commensurability of physical quantities 4) Non-time Schrodinger´s equation Non-time Schrodinger´s equation, examples (infinitely deep potential well, linear oscillator) 5) Time Schrodinger´s equation Time equation, stationary and non-stationary solution, continuity equation 6) Radial field movement Moment of momentum and its quantization, conservation of moment of momentum 7) Hydrogen Atom States of electron, spliting of energy levels in magnetic field (not considering spin) 8) Elementary quantum theory of scattering Scattering states, overbarrier reflection and tunnel effect 9) Spin theory 1/2 Experiments documenting spin existence, mathematical spin decription1/2. Zeeman´s effect (considering spin) 10) Identical particles indeterminancy principle Indeterminancy principle, bosons, fermions, Pauli´s exclusion principle 11) Gibb´s distributions Microcanonical, canonical and grandcanonical distribution 12) Quantum statistics of ideal Gates Bose-Einstein and Fermi Dirac statistics, degenerated fermion gas 13) Specific heats theory Classical theory of specific heats and equipartition theorem, quantum theory of specific heats 14) Heat radiation history of finding of formula for spectral density radiation, Planck´s law

Learning activities and teaching methods
Monologic (reading, lecture, briefing)
Learning outcomes
Elementary quantum mechanics according to Schrodinger's application. Elementary statics physics. Explanation of particular mathematical methods (operators, mathematic statistics).
Understanding basic principles of quantum mechanics and statistic physics.
Prerequisites
Physics I-IV, math. analysis

Assessment methods and criteria
Oral examination

An active knowledge of the subject matter as presented by the teaching plan of the course.
Recommended literature
  • Blažek J.:. Úvod do termodynamiky a statistické fyziky. Skripta PF JU, České Budějovice, 1993.
  • Čulík F., Noga M.:. Úvod do štatistickej fyziky a termodynamiky. Bratislava 1982.
  • Kvasnica J.:. Statistická fyzika. Academia, Praha 1983.
  • Marx G.:. Úvod do kvantové mechaniky. Praha 1965.
  • Pišút J., Černý V., Prešnajder P.:. Zbierka úloh z kvantovej mechaniky. Bratislava 1985.
  • Pišút J., Gomolčák L., Černý V.:. Úvod do kvantovej mechaniky. Bratislava 1983 (2. vydání).
  • Skála, L. Úvod do kvantové mechaniky. Academia, Praha, 2005. ISBN 80-200-1316-4.
  • Svoboda E., Bakule R.:. Molekulová fyzika. Praha 1992.


Study plans that include the course
Faculty Study plan (Version) Category of Branch/Specialization Recommended year of study Recommended semester
Faculty: Faculty of Education Study plan (Version): Teacher training in physics (2) Category: Pedagogy, teacher training and social care 2 Recommended year of study:2, Recommended semester: Summer
Faculty: Faculty of Education Study plan (Version): Teacher training in physics and information technology (1) Category: Pedagogy, teacher training and social care 3 Recommended year of study:3, Recommended semester: Summer
Faculty: Faculty of Education Study plan (Version): Teacher training in physics (2) Category: Pedagogy, teacher training and social care 2 Recommended year of study:2, Recommended semester: Summer