After successful completion of the course, students are able to understand the physical, chemical and mathematical methods and fundamentals of materials science, which are necessary for the conception and production of electronic, photonic and sensor-actuated structures, components and components. Further, to understand modern applications of magnetic materials in the field of sensors, storage media and magnetic beads.
Comprehensive knowledge of the materials that form the basis of modern nanoelectronics, nanophotonics and microsystems technology. Element and compound semiconductors of Groups IV and III-V, as well as oxide ceramics are the main focus on the material side.1-, 2-, and 3-dimensional structures, key processes, layer generation including MBE and ALD, selective growth processes for (quasi) 1-, 2-dimensional structures, such as nanodots and nanowires, and in situ and ex situ material characterization methods.
In the field of magnetism, the magnetic basics of small structures are treated with the corresponding applications of synthetic antiferromagnets, sensors, storage media and magnetic beads.
Allotropes of carbon and their fabrication.