Theoretical basis and selected experiments to determine the properties of neutrinos and their interactions (mass, spin, helicity, chirality, oscillations, charge-parity violation, interactions with leptons and quarks) and implications on physics beyond the Standard Model of elementary particles as well as on Cosmology.

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.

Concepts and tools in physics: mechanics of point-like and rigid bodies, elasticity theory, elements of hydrostatics and hydrodynamics, periodic motion and mechanical waves.The "way of thinking" and the methodology in Physics. Magnetism, Refraction and Diffraction of Waves, Elements of Quantum Mechanics with applications to Spectroscopy, Thermodynamics, Phase Transitions, Transport Phenomena.

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

Introduction to the "way of thinking" and the methodology in Physics. The Chapters treated are Magnetism, Refraction and Diffraction of Waves, Elements of Quantum Mechanics with applications to Spectroscopy, Thermodynamics, Phase Transitions, Transport Phenomena.

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

Introduction to the way physicists think and work with the help of concept questions, demonstration experiments and problem solving. Wherever possible, applications from thermodynamics, electricity and magnetism are taught from the areas of the degree programmes.

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

Electricity and magnetism, electrostatic forces, fields and potentials, currents and circuits, magnetic fields, induction, Maxwell's equations, electromagnetic waves, electric and magnetic fields in materials.

Introductory lab course in experimental physics

This lecture will provide a detailed introduction to radiotherapy treatment planning. The course considers the physical interactions of radiation in tissue, the mathematical aspects of treatment planning and additional aspects of central importance for radiotherapy planning.

The aim of this lecture series is to introduce the role of physics in state-of-the art medical research and clinical practice. Topics to be covered range from applications of physics in medical implant technology and tissue engineering, with a strong focus on X-ray-based imaging, to its role in interventional and non-interventional therapies.

The course is dedicated to introduce MAS students from Medical Physics to the field of radiodiagnostic and nuclear medicine. Dedicated practicals will illustrate the theory with an emphasis on the relationship between dose and image quality as well as the security problems related to the work with radiations.

Physics in today's high-tech smartphone. Examples: network topology and scratch proof glass, spin-orbit coupling - brighter displays, GPS and general theory of relativity, electromagnetic response of matter (transparent metals for displays, GPS signal propagation), light-field cameras, CCD and CMOS light sensors, physics stops Moore's law, meta-materials for antennas, MEMS sensor physics, etc.

In this lecture, symmetry and conservation law are applied to derive wave functions for elementary particles. Relativistic wave functions are analysed and applied for massive and massless particles. Different ideas on antiparticles are explored.

In Physics of Food Colloids the principles of colloid science will applied to the aggregation of food materials based on proteins, polysaccharides, and emulsifiers. Mixtures of such raw material determine the appearance and performance of our daily food. In a number of examples, colloidal laws are linked to food science and the manufacturing and processing of food.

Understanding glaciers and ice sheets with simple physical concepts. Topics include the reaction of glaciers to the climate, flow of glacier ice, temperature in glaciers and ice sheets, glacier hydrology, glacier seismology, basal motion and calving glaciers. A special focus is the current development of the ice sheets of Greenland and Antarctica.

The lecture provides an overview of the fundamental working principles of semiconductor optoelectronic devices.Students will get the opportunity to deepen the knowledge gained in lectures by attending exercise sessions provided in the framework of the lecture.

Planetary science encompasses the study of the physical and chemical nature of planetary bodies both in the Solar System and in extrasolar systems. The formation of planets, the forces that shaped their orbits and the processes that molded their interiors are part of planetary science. Understanding these complex phenomena requires knowledge from various geo- and astrophysically-related fields.

This course imparts the physical fundamentals as well as new observational results for the overall flow of genesis of stars and planet systems.