Title :
Non-contact investigation of metal-nanostructure conductivity
Author :
Fahsold, G. ; Kolb, T. ; Pucci, A.
Author_Institution :
Kirchhoff-Inst. fuer Phys., Heidelberg Univ., Germany
fDate :
27 Sept.-1 Oct. 2004
Abstract :
The dynamic conductivity of metal nanostructures is determined by material properties, the morphology in the volume of the nanostructure, its shape and its size, and by the structure and the chemical composition at the surfaces. IR-spectroscopic investigation of dynamic charge transport allows a distinction between such contributions. We performed in-situ IR spectroscopic measurements of metal ultrathin (<10 nm) films on non-metal substrates. Our thin-film model based calculations of IR spectra indicate depolarisation for inhomogeneous films, quantum confinement for homogeneous films, adsorbate induced charge carrier relaxation and charge transfer at thin film surfaces, and they provide a measure of the dc-conductivity of these nanosized metals in a non-contact fashion.
Keywords :
copper; electrical conductivity; electrical resistivity; infrared spectra; iron; metallic thin films; nanostructured materials; silver; size effect; surface composition; surface morphology; Ag; Cu; Fe; IR spectra; IR spectroscopic measurements; charge carrier relaxation; charge transfer; dc conductivity; depolarisation; dynamic charge transport; inhomogeneous films; material properties; metal nanostructure conductivity; metal ultrathin films; nanosized metals; nanostructure morphology; nonmetal substrates; quantum confinement; surface chemical composition; thin film surfaces; Chemicals; Conductivity; Infrared spectra; Material properties; Nanostructures; Performance evaluation; Shape; Spectroscopy; Surface morphology; Transistors;
Conference_Titel :
Infrared and Millimeter Waves, 2004 and 12th International Conference on Terahertz Electronics, 2004. Conference Digest of the 2004 Joint 29th International Conference on
Print_ISBN :
0-7803-8490-3
DOI :
10.1109/ICIMW.2004.1422338
