Bose-Einstein condensation and superfluidity in solid state systems 1100-BECSSST

Lecture 1 and 2. Bose-Einstein condensation in atomic systems - the dream and discovery.
History of the experimental observation of BEC state in atomic systems. Most important experimental results including techniques of laser cooling, absorption spectroscopy and interferometry.

Lecture 3. Solid state systems - introduction
Most important properties of solid state systems. This include: band diagrams, electron and hole concepts, doping. Further on we will focus on the simple heterostructures - interfaces, quantum wells, quantum wires, quantum dots.

Lecture 4. Quasiparticles.
Excitations in the solid state from the point of view of new quasiparticle creation. Concept of excitons (ground and excited states), phonons, photons, magnons with the possibility for those particles to condense.

Lecture 5. More complex quasiparticles.
Various types of polaritons: phonon-polaritons, exciton-polaritons, plasmon-polaritons, magnon-polaritons. Dressed states.

Lecture 6. Exciton-polaritons.
The properties of exciton-polaritons in details as they are the best candidates to observe BEC. At this point it is important to construct the complex photonic systems: the Bragg mirrors and microcavity structures. Differences between the spontaneous emission, weak coupling and strong coupling. Similarity of microcavity with quantum wells to VECSEL structure.

Lecture 7. Bose-Einstein condensation of exciton-polaritons.
The first experiment demonstrating polaritonic BEC. Differences between the atomic and polaritonic BEC. The first and second order coherence.

Lecture 8. Bose-Einstein condensation of exciton-polaritons - details.
Differences between the BEC state and polariton laser. Experimental results of polariton lasing in various type semiconductor systems: II-VI, III-V wide and narrow bandgap materials. Josephson effect.

Lecture 9. Superfluidity of exciton-polaritons.
Short history of experimental observation of superfluid state in various systems. The properties of the superfluid state. The first experimental results that demonstrate the superfluid state of exciton-polaritons.

Lecture 10. Full and half vortices - stationary.
The appearance of the vortices at the beak of (or at the birth) of the superfluid state. Introduction and the most important physical properties of the classical and quantum vortices. Properties of full and half vortices with the most prominent experimental results in this subject.

Lecture 11. Vortices - propagating in the wake of an obstacle.
Vortices propagating in the wake of an obstacle. Role of the superfluid velocity: supersonic and subsonic. Solitons.

Lecture 12. BEC of pure excitons.
Before the exciton-polariton physics, the first attempt to create the condensed state were performed with pure excitons. The most important results in excitonic BEC (direct excitons, indirect-excitons, Cu2O excitons).

Lecture 13. Magnons.
The concept and the most important results from the BEC of magnons and short look at any other BEC possibility in solid state system.

Lecture 14. Summary. Students will create their own mind map of the subjects discussed during the lecture. Work in the group or individually. Personal notes and discussed publications are required in order to attend this lecture. Students will discuss on the possibility of practical implementation of BEC and superfluidity (brainstorm technique).

Lecture 15.
Exam oral or written report.