Material Modelling

The lecture focuses on various methods of nanofabrication (optical, electron beam lithography, focused ion beam) and newer emerging techni¬ques (x-ray lithography, nanoimprint, etc.). In particular the physical principles are discussed and limitations for the various methods given. Various synthesis and crystal growth methods for advanced semiconductor nanostructures will be further introduced such as chemical and physical vapor phase epitaxial techniques (MOVPE, MBE, etc.) and the physical growth principles of 0D,1D, and 2D materials highlighted. Examples will be given where these low-dimensional nanostructures are implemented into cutting-edge technological applications. The second part of this lecture deals with specific nanoanalytical methods required for characterization of structural, surface and atomic properties of nanofabricated and synthesized materials. These include electron microscopy, surface analytical methods, ion beam analytical techniques, x-ray techniques, and some new sophisticated techniques, such as atom probe tomography, etc.

After successful participation and engagement in the lecture "Material Modelling" students will have gained:

1. basic knowledge in nanofabrication and analysis of mainly semiconductor-based devices,
2. the capability to select and evaluate specific nanofabrication methods relevant for nanotechnological applications,
3. the possibility to explore the limits of the various methodologies,
4. the capability for structural, atomic and interface specific analysis of nanostructured materials, and
5. the important knowledge in understanding the complex interplay between material synthesis, structural and electronic properties of materials, and their effect on functionalities in cutting-edge device applications.

Basics in Solid State Physics

Lecture: Lecture presentation

Class-room Presentation, Lab visit

Lecture Notes and references therein

In a written exam the learning success is checked using comprehension questions and calculation problems.