This laboratory course provides basic training of experimental skills. These are experimental design, implementation, measurement, data analysis and interpretation, as well as error analysis. The experimental work has to be complemented by a concise written report, which trains the scientific writing skills.Manuals for the individual experiments are available in English.

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

Implementation of experiments in condensed matter physics. Planning, design, realisation, evaluation, and interpretation of the experiments.

The lecture discusses the basic physics concepts of quantum dot charge and spin qubits from the experimental viewpoint. Among them are the Coulomb and Spin blockade, qubit manipulation techniques including elements of circuit QED, relaxation and decoherence mechanisms as well as qubit read-out techniques.

The aim of the project is to give the student experience in working in a research environment, carrying out physics experiments, analysing and interpreting the resulting data.

The aim of the project is to give the student experience in working in a research environment, carrying out physics experiments, analysing and interpreting the resulting data.

No description available.

Introduction to the concepts and tools of physics with the aid of demonstration experiments: mechanics and oscillations

Fundamentals of Thermodynamics and Statistical Mechanics, as well as elements of Electromagnetism

The course covers the foundations of semiconductor nanostructures, e.g., materials, band structures, bandgap engineering and doping, field-effect transistors. The physics of the quantum Hall effect and of common nanostructures based on two-dimensional electron gases will be discussed, i.e., quantum point contacts, Aharonov-Bohm rings and quantum dots.