Bulk and surface plasmons in highly nanoporous gold films

Abstract: The far-field plasmonic behaviour of nanoporous gold films with void densities, f, ranging from 60% to 90% has been investigated and modelled. These layers have good dc conductivity and quite different nanostructure to traditional porous layers in which the metal percolates. Our gold films with f above 70% have high thermal emittance for a conductor at their thicknesses, and their flat spectral response at visible and near infrared wavelengths is not metal-like. We derive effective optical constants which beco… Show more

“…It follows primarily because nanoporous thin films when percolating behave as if they are homogeneous with an effective plasma frequency  P * which is much less than the  P value in dense gold. The quantitative link between  P * and  P has been derived previously [8,9] both in the general Bergman-Milton (B-M) formalism and in terms of the quasistatic effective medium approach due to Bruggeman [33]. The result in the Bruggeman approximation is that…”

“…The fabrication process of the three dimensional nanoporous gold films is similar to that described previously [8][9][10]. Briefly, alloy films of AuAl 2…”

“…Ideally to explore critical percolation parameters, we would like to make a set of samples with the same f c value but different f . However every change in f with the same vacuum deposition conditions leads in practice to a different morphology, with our etching process involving much gold atom movement [8][9][10]. A universal curve that follows may mean that in random self-supporting systems in 3-dimensions, self-assembled porous structures at low f always do this, but further work is needed to rule out such growth along the same critical curve.…”

“…Direct measurement of  P * gives an independent and useful measure of f using the B-M formalism [9]. The fall is due to a combination of the drop in average free electron density, and a rise in carrier effective mass m* in the complex network as f falls towards f c [8,9].…”

“…The properties of this material near percolation are assuming technical importance as a result of the growing interest in composite nanomaterials. Emerging applications of nanoporous gold include surface-enhanced Raman scattering spectroscopy [6,7], solar energy, thermal radiation and photonics [8,9,10], capacitive biosensors [11], supercapacitors [12] and chemical Percolation theory has an extensive history [15], which we will draw on for analysis of our data along with basic principles in phase transition theory [16]. The application of percolation theory to experimental materials has been predominantly for dc and ac electrical data on composites made from powders [17][18][19], while natural structures such as porous rocks [20] and sea ice [21] have also been studied.…”

Percolation in nanoporous gold and the principle of universality for two-dimensional to hyperdimensional networks

“…It follows primarily because nanoporous thin films when percolating behave as if they are homogeneous with an effective plasma frequency  P * which is much less than the  P value in dense gold. The quantitative link between  P * and  P has been derived previously [8,9] both in the general Bergman-Milton (B-M) formalism and in terms of the quasistatic effective medium approach due to Bruggeman [33]. The result in the Bruggeman approximation is that…”

“…The fabrication process of the three dimensional nanoporous gold films is similar to that described previously [8][9][10]. Briefly, alloy films of AuAl 2…”

“…Ideally to explore critical percolation parameters, we would like to make a set of samples with the same f c value but different f . However every change in f with the same vacuum deposition conditions leads in practice to a different morphology, with our etching process involving much gold atom movement [8][9][10]. A universal curve that follows may mean that in random self-supporting systems in 3-dimensions, self-assembled porous structures at low f always do this, but further work is needed to rule out such growth along the same critical curve.…”

“…Direct measurement of  P * gives an independent and useful measure of f using the B-M formalism [9]. The fall is due to a combination of the drop in average free electron density, and a rise in carrier effective mass m* in the complex network as f falls towards f c [8,9].…”

“…The properties of this material near percolation are assuming technical importance as a result of the growing interest in composite nanomaterials. Emerging applications of nanoporous gold include surface-enhanced Raman scattering spectroscopy [6,7], solar energy, thermal radiation and photonics [8,9,10], capacitive biosensors [11], supercapacitors [12] and chemical Percolation theory has an extensive history [15], which we will draw on for analysis of our data along with basic principles in phase transition theory [16]. The application of percolation theory to experimental materials has been predominantly for dc and ac electrical data on composites made from powders [17][18][19], while natural structures such as porous rocks [20] and sea ice [21] have also been studied.…”

Percolation in nanoporous gold and the principle of universality for two-dimensional to hyperdimensional networks

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