Course detail
Quantum Chemistry
FCH-MA_KVCHAcad. year: 2023/2024
Basic conceptions of quantum mechanics, operators, wave functions end eigen values, Heisenberg´s principle of uncertainty and its impacts.
Simple quantum mechanic models (particle in one and three dimensional potential hole, harmonic oscillator, rigid rotator, hydrogen atom).
Chemical bound, Born-Oppenheimer approximation, hydrogen molecular ion, LCAO-MO approximation, hybridization and localization of bounds, VSEPR method, molecular orbitals in solids.
Language of instruction
Number of ECTS credits
Mode of study
Guarantor
Offered to foreign students
Entry knowledge
Basic physics - mass point motion, electrostatic field
Rules for evaluation and completion of the course
Exams are spread over whole examination period based on individual student asks.
none
Aims
Student will obtain practical knowledge necessary for the application of the quantum mechanics apparatus. He will be friendly with micro and macrosystems behaviour based on the solution of electronic strucure of the atoms and molecules solved by the quantum mechanics basic principles.
Study aids
Prerequisites and corequisites
Basic literature
Atkins P. W.: Physical Chemistry. Oxford University Press, Oxford 2006. (EN)
Recommended reading
Elearning
Classification of course in study plans
- Programme NPAP_ENVI Master's 1 year of study, winter semester, compulsory
Type of course unit
Lecture
Teacher / Lecturer
Syllabus
2. Elementary basis of the quantum mechanics. Operators and their characteristic values.
3. Quantum mechanics postulates. Heisenberg principle of uncertainty.
4. Simple quantum mechanic systems. Particle in the potential hollow. Tunnel effect.
5. Linear harmonic oscillator.
6. Spherical coordinate system. Rigid rotator.
7. Hydrogen atom.
8. Moment of movement in the quantum mechanics and its properties.
9. Orbital and spin moments. Combining of the moments.
10. Electronic structure of atoms. Many particle problem in quantum mechanics. Permutation operators. Slater determinant. Pauli's exclusion principle. Electronic configuration of atoms and atomic terms.
11. Chemical bound. H2+ molecular ion. Heilter-London model of H2 molecule.
12. Born-Oppenheimer approximation. Molecular orbitals. LCAO MO approximation. Localized and delocalized molecular orbitals. Hybridization.
13. VSEPR method and molecular geometry. Crystal field theory. Chemical bound in solids. Semi empiric methods of molecular orbitals.
Guided consultation in combined form of studies
Teacher / Lecturer
Elearning