We standardize the approach to predict composite permeability, mu(eff), to determine the reflection (R), transmission (T), and absorption (A) using the generalized effective medium theory. For stainless steel (SS) spheres and fibers, we calculate the inclusion permeability based on the effective susceptibility generated by eddy currents in a time-varying magnetic field. This gives reasonable agreement with measured. mu(eff) when used in the Bruggeman theory and agreement with R, T, and A within 10%. For SS flakes, we fit the imaginary component of mu(eff) to a single-peak Lorentzian for each loading and use typical fitting parameters to predict mu(eff) and, ultimately, R, T, and A within 5%. The fitting exponent t was constant for all frequencies for a given inclusion shape (4.7, 1.6, and 1.7 for spheres, fibers, and flakes, respectively) and A(x) typically varied with inverse volume loading rather than percolation threshold. Interestingly, at percolation for the fibers, Ax approached a constant that approximately equaled the observed percolation threshold.

• 出版日期2015-8