SFB 1083: Structure and Dynamics of Internal Interfaces

Basic data for this project

Description

Internal interfaces between two solids play a decisive role in modern materials sciences and their technological applications. Among the most prominent examples are certainly semiconductor devices which have been miniaturised to such an extent that their optical and electronic properties are determined decisively by interfaces. In the future, the importance of internal, solid/solid inter-faces is expected to increase even further due to the development of new hybrid materials. One type of these materials combines specific properties of metals or inorganic semiconductors on the one hand, with those of organic or biomaterials on the other hand. Another type of composite material is created by stacking different two-dimensional solids, such as graphene or transition metal dichalcogenides, together. In both cases, the interaction of different solids across the interface and specific interface properties are crucial to the resulting functionality. Despite their enormous importance, our microscopic understanding of internal interfaces is lagging behind that of volume or surface properties. The main reason for this knowledge gap is the experi¬mental difficulty to detect and isolate the weak interface signature from the signals of the dominant bulk. The objective of the collaborative research centre SFB 1083 is to close this gap by collaboration between researchers from chemical synthesis, semiconductor physics, surface science, structural analysis and laser spectroscopy. Primarily, our research is not directed towards specific functional materials, as those generally consist of many, frequently not well-defined interfaces. Instead, we focus on model systems with specially prepared internal interfaces. We structurally characterise these interfaces on the atomic level and investigate their optical and electronic properties system-atically. In this way, we want to achieve a detailed microscopic understanding of chemical bonding, electronic coupling and energy transfer for different classes of heterointerfaces. We then can make use of this knowledge and tailor interfaces for specific applications and construct devices with novel properties and functions.