Semiconductor nanostructures with anisotropic optical and electronical properties present an important material class for bottom-up design of nanodevices and optical functionalization of hybrid optically active/passive nanostructures. This project is aimed at the investigation and understanding of dimensionality and directional dependencies of excitonic elementary excitations in single nanorods as a prerequisite for using them, e.g., in nanorod-based complexes for application purposes and fundamental physics. The focus is on the peculiar high degree of linearly polarized emission in wurtzite-type nanorods. The symmetries and wave functions of excitons in colloidal CdSe nanorods, the excitonic fine structures, the radiative lifetime, the density of states as well as interaction with other elementary excitations (phonons, charged excitons, biexcitons) will be studied by spectroscopy on a single nanorod level with temperature, excitation energy, pump power, nanorod size and shape, ZnS shell thickness and shape, nanorod environment and growth regimes as external parameters. To understand the specific action of highly polarized, oriented emitters with close-lying energy states of different symmetry (the nanorods) in functional nanoensembles, we study nanorods in more complex structures, such as ensembles of aligned nanorods, nanorod/dye and nanorod/metal wire complexes and determine electronic coupling, energy transfer, light conversion and mutual excitation inside the complexes.

DFG-Verfahren Schwerpunktprogramme

Teilprojekt zu SPP 1165:  Nanodrähte und Nanoröhren: von kontrollierter Synthese zur Funktion