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

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Part A:Introduction to mechanics: kinematics, Newton's Laws, energy and momentum, rotation of solid bodies, movement in a central field, oscillations and waves.Part B: electrostatics, electric current, simple circuits, magnetic field, magnetic induction, Maxwell's equations, elements of optics.

The course treats the fundamental aspects of modern Electronics, Quantum mechanics and Atomic physics.

Introductory course on quantum and atomic physics including optics and statistical physics.

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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.

Introduction to ultrafast laser physics with an outlook into cutting edge research topics such as attosecond science and coherent ultrafast sources from THz to X-rays.