Optical properties of square lattices of gold nanoparticles

We reanalyse optical measurements on two-dimensional lattices of ultrafine gold particles, produced by electron beam lithography. The spectra exhibit a distinct absorption peak due to the localized plasma resonance of the conduction electrons in the particles. The theoretical modeling used rigorous solutions, in the long-wavelength limit, for the polarizability of oblate spheroids and truncated spheres on a substrate. The dipole-dipole interactions between the particles in the square lattice were taken into account. We find good agreement between experimental and theoretical absorption peak positions for the case of oblate spheroids, but not for truncated spheres. Peak widths and minimum transmittances also show satisfactory agreement with theory

Optical properties of square lattices of gold nanoparticles

We reanalyse optical measurements on two-dimensional lattices of ultrafine gold particles, produced by electron beam lithography. The spectra exhibit a distinct absorption peak due to the localized plasma resonance of the conduction electrons in the particles. The theoretical modeling used rigorous solutions, in the long-wavelength limit, for the polarizability of oblate spheroids and truncated spheres on a substrate. The dipole-dipole interactions between the particles in the square lattice were taken into account. We find good agreement between experimental and theoretical absorption peak positions for the case of oblate spheroids, but not for truncated spheres. Peak widths and minimum transmittances also show satisfactory agreement with theory

Electrical and optical properties of thin films consisting of tin-doped indium oxide nanoparticles

Electrical transport and optical properties were investigated in porous thin films consisting of In2O3:Sn (indium tin oxide, ITO) nanoparticles with an initial crystallite size of 16 nm and a narrow size distribution. Temperature dependent resistivity was measured in the 77<t<300 K temperature interval for samples annealed at a temperature in the 573tA1073 K range. Samples annealed at 573t A923 K exhibited a semiconducting behavior with a negative temperature coefficient of the resistivity (TCR). These data were successfully fitted to a fluctuation induced tunneling model, indicating that the samples comprised large conducting clusters of nanoparticles separated by insulating barriers. Samples annealed at tA = 1073 K displayed a metallic behavior with no signs of insulating barriers; then the TCR was positive at t> 130 K and negative at t<130 K. Effects of annealing on the ITO nanoparticles were investigated by analyzing the spectral optical reflectance and transmittance using effective medium theory and accounting for ionized impurity scattering. Annealing was found to increase both charge carrier concentration and mobility. The ITO nanoparticles were found to have a resistivity as low as 2 × 10-4 cm, which is comparable to the resistivity of dense high quality In2O3:Sn films. Particulate samples with a luminous transmittance exceeding 90% and a resistivity of 10-2 cm were obtained