Carbon nanotube opto-electronics and plasmonics exploit novel fascinating physical phenomena and are among the most promising research areas for nanotechnology providing functional nano-objects for data transfer and processing at ultimate device densities. We propose interfacing these two technologies to create the first efficient electricallydriven multiplexing surface plasmon source. In the first two steps, we explore the laws governing the near-field coupling between nanotubes and plasmon-guiding metallic nanostructures. Utilizing high-resolution optical microscopy we probe the electrical fields along single nanotube / metal waveguides visualizing both localized and propagating excitations. Finally, we use an electroluminescent nanotube to launch surface plasmons on demand in addressable waveguides. Our team is formed by peers in the field of plasmonics, near-field microscopy and carbon nanotube technology providing the expertise required to addressing this challenging project.

DFG-Verfahren Sachbeihilfen

Internationaler Bezug Frankreich, Italien

Beteiligte Personen Dr. Maria Allegrini; Dr. Alexandre Bouhelier