Load:

1. komponenta
Lecture type  Total 
Lectures 
60 
Exercises 
30 
Seminar 
30 
* Load is given in academic hour (1 academic hour = 45 minutes)

Description:

COURSE AIMS AND OBJECTIVES: Mastering the basic concepts of quantum mechanics, understanding basics of quantum physics and functioning of simple quantum systems. Qualitative and informative decriptions and explanations also of some more complicated quantum systems.
COURSE DESCRIPTION AND SYLLABUS:
 Introduction  conceptual and historical
 Quantum of energy, and photons  the quanta of light (electromagntic radiation) Blackbody radiation, derivation of Planck's formula. Photoelectric effect, Compton effect, the dual particlewave nature of photons.
 Particlewave nature of matter and probability waves The Bohr model of hydrogen atom. De Broglie hypothesis on the wave nature of microparticles and its confirmation by the DavisonGermer experiment. The particlewave duality of microparticles and necessity of associating to them a wave function  a probability amplitude. The probabilistic character of quantum physics in contrast to classical determinism. Heisenberg uncertainty relations.
 Elements of wave formalism and motivations for the postulates of quantum mechanics
 The postulates of quantum mechanics. Operators, eigenfunctions and eigenvalues. Illustrations thereof by simple examples.
 The simplest bound state The needed elements of mathematical formalism. Schrödinger equation for a particle in the infinitely deep rectangular potential.
 Superposition principle in quantum mechanics
 Commutation properties of operators, and compatible vs. complementary observables
 Time evolution, conservation theorems and symmetries (including parity)
 More advanced onedimensional problems for bound and unbound states Harmonic oscillator. Scattering on flat obstacles  a simple step and rectangular potential. Tunneling through the rectangular potential. A rectangular onedimensional potential well of a finite depth: bound states and their energies.
 Transition to systems with more than one degree of freedom  i.e., multiparticle or multidimensional systems. Symmetric and antisymmetric twoparticle wave functions.
 Transition to the threedimensional space and introduction of angular momentum Introduction of spin in an intuitive way. Bosons and fermions, and some remarks concerning the connection between spin and statistics of quantum objects.
 Hydrogen atom and similar systems
 The Pauli priciple and qualitative description of more complicated atom and molecular systems.

Literature:

 R. L. Liboff: Introductory Quantum Mechanics
 R. Eisberg, R. Resnick: Quantum Physicsof Atoms, Molecules and Solids, Nuclei and Particles
 D. Klabučar: nastavni materijali na predavanjima, dostupni u knjižnici PMF  Fizičkog odsjeka Sveučiilšta u Zagrebu, a velikim dijelom i na internetskoj stranici http://www.phy.hr/~klabucar/
 F. S. Levin: An introduction to Quantum Theory
 I. Supek: Teorijska fizika II

Prerequisit for:

Enrollment
:
Passed
:
Fundamentals of physics 4
Attended
:
Classical mechanics 1
Examination
:
Passed
:
Classical mechanics 1
