Implementation of experiments in quantum electronics. Planning, design, realisation, evaluation, and interpretation of the experiments.

This course builds up on the material covered in the Quantum Optics course. The emphasis will be on analysis of dissipative quantum systems and quantum optics in condensed-matter systems.

No description available.

The course presents fundamental aspects of light-matter interaction in semiconductor materials, from basic research topics to opto-electronic devices.

Description of open quantum systems using quantum trajectories. Cascaded quantum systems. Decoherence and quantum measurements. Elements of single quantum dot spectroscopy: interaction effects. Spin-reservoir coupling.

Introduction to the concepts and tools in physics with the help of demonstration experiments: mechanics of point-like and ridged bodies, periodic motion and mechanical waves.

Physics I is an introduction to wave phenomena and fundamental concepts of thermodynamics.

The goal of the Physics II class is an introduction to quantum mechanics

Introduction to the concepts and tools in physics with the help of demonstration experiments: electromagnetism, optics, introduction to modern physics.

No description available.

Classical and semi-classical introduction to Quantum Electronics. Mandatory for further elective courses in Quantum Electronics. The field of Quantum Electronics describes propagation of light and its interaction with matter. The emphasis is set on linear wave and beam propagation in dispersive media, interference, diffraction, optical anisotropic materials, waveguides and lasers.

This course gives an introduction to the fundamental concepts of Quantum Optics and will highlight state-of-the-art developments in this rapidly evolving discipline. The topics covered include the quantum nature of light, semi-classical and quantum mechanical description of light-matter interaction, laser manipulation of atoms and ions, optomechanics and quantum computation.

New platforms for exploring quantum many-body physics include moire systems in van der Waals materials, terahertz metamaterials with ultrastrong light matter coupling, cold atoms in optical lattices with tunable geometry and ensembles of atoms or molecules with non-local interactions. This course will review concepts central to these systems.