Optical properties and solar selectivity of coevaporated Co-Al2O3 composite films

Abstract

Co‐Al₂O₃ composite films were produced by electron‐beam coevaporation in a system with elaborate process control. The deposits were analyzed by transmission electron microscopy, electron diffraction, Auger electron spectroscopy, secondary ion mass spectroscopy, Rutherford backscattering, field ion microscopy, mechanical stylus measurements, and electrical dc and ac measurements. A uniform separated‐grain structure with regular hcp Co particles embedded in Al₂O₃ was found for Co contents (f_Cos’) up to ∼30 vol %. The complex dielectric permeability ε̄ was evaluated in the 0.3≲λ≲40‐μm wavelength range for samples with 0.11≲ f_Co ≲0.60 by carefully selected combinations of spectrophotometric transmittance and reflectance data. Numerical accuracy and internal consistency were investigated. Effective medium theories for ε̄ were derived by applying classical scattering theory to spherical random unit cells defined so as to properly represent a number of typical microgeometries. The formulations due to Maxwell Garnett, Bruggeman, and others were thus rederived in a unified way. Large‐size limits of validity and extensions to nonspherical particles were treated. It was found that the Maxwell Garnett theory could reproduce the experimental ε̄’s in detail at low f_Co provided that some Co was taken to be dispersed in the insulating matrix. At larger f_Co’s we found discrepancies which are likely to be due mainly to dipole‐dipole coupling among adjacent particles. A comparison of the experimental ε̄’s and the rigorous Bergman–Milton bounds, which hold irrespective of detailed microgeometry, gave several interesting results: the ε̄’s varied monotonically along one of the bounds for isotropic materials as f_Co was increased, at large f_Co we found evidence for anisotropy, and at λ≊12.5 μm we noted certain cases of disagreement with even the most generous bounds. The empirical ε̄’s were used to construct surfaces which combine a high solar absorptance a_s with a low hemispherical thermal emittance e^H. From a computer optimization study we found that a_s =0.95 and e^H =0.07 could be obtained with 0.07 μm of Co‐Al₂O₃ ( f_Co≊0.6) antireflected with 0.07 μm of Al₂O₃ and laid on Ni. These results were verified by measurements on samples which approximate the ideal design.