Electrical conductivity of sol-gel derived metal nanoparticles

Abstract

Electrically conducting films of thickness ∼ 2 μm have been prepared on ordinary glass slides by growing ultra-fine particles of iron and copper, respectively, from a suitable precursor sol. The diameters of metal particles can be varied from 3-13 nm by controlling the heat-treatment schedule of the sol coating. Resistivity measurements (d.c.) have been carried out over the temperature range 80-300 K. The resistivity values in the range 0.0001-0.0039 Ω cm have been obtained depending on the particle diameter and the type of metal used. The effective Debye temperature θD for the different nanoparticle systems have been estimated by fitting the experimental data to the Ziman equation. θD is found to vary from 346-408 K for iron with the particle size in the range 3.4-9.5 nm. The values obtained for copper are 243-307 K with particle diameters covering a range of 5.9-12.6 nm. © 1992 Chapman & Hall.