The transport of free electrons in metal nanowires (MNW) is of interest for microelectronic applications as the resistive generation of heat consumes electrical energy and can cause overheating in future integrated-circuit architectures. Any engineering of MNW interconnects needs specific knowledge on the influence of temperature, size and crystalline structure on the charge transport. We want to generate such specific knowledge by performing infrared-spectroscopic experiments. Resonant excitation of free charge carriers in metal nanoparticles has numerous applications in technology and life science. MNW of few micron lengths should show plasmon resonances in the infrared range. These resonances promise near-future applications in position-sensitive vibrational spectroscopy and a pathway to a tailoring and a metrology of MNW. We aim at giving experimental evidence for MNW plasmons in the infrared range and at a demonstation how sharpness and frequency of these plasmons can be adjusted for a specific functionalization of MNW. A thermal instability of a MNW is of high technological relevance. It can cause device failure, but on the other hand, it can be utilized for a nanostructure tailoring. We intend to investigate the time and temperature dependence of such instabilities under various conditions to open pathways for their controlled utilization.

DFG-Verfahren Schwerpunktprogramme

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