Course syllabus for Applied quantum physics

Prerequisites are basic quantum physics knowledge, gained for example through the course Quantum Physics (FUF040), and knowledge of mathematics and mechanics corresponding to the basic courses in mathematics and mechanics.

This course is a continuation of the first course in Quantum Physics (FUF040). Here quantum physics is again applied on elementary phenomena, its rôle for the technical physics is further elucidated including modern technological applications. Its realization in a number of different important systems is noticed through exercises and projects.

- compute energy levels for systems where approximation methods must be used. - solve time-dependent systems. - describe the line of thought between the fundamental Schrödinger equation and the rule to build up the periodic system of the elements. - describe chemical bonding from quantum mechanical principles. - have gained some experience in choosing suitable model and approximation for treatment of specific quantum systems.

This course is a continuation of the the first course in Quantum Physics (FUF040). - Here quantum physics is applied on elementary phenomena - Interactions of degrees of freedom in many-electron atoms are discussed (spin-orbit interaction, fine structure, Pauli principle etc) - The periodic table of the elements and the electronic structure of the elements are discussed - Approximation methods for many-electron systems and time-dependent perturbation theory is introduced and applied. - The physics of molecules is introduced (types of molecular binding, molecular orbitals, diatomic molecules, molecular spectra, dynamics). - The role of quantum physics for the technical physics is further elucidated including applications.

Lectures and problem solving classes are given. The course has one compulsory experimental excersice.

Home assignments, experimental work and written exam.