Theoretical model of the impedance of a fractal metal-electrolyte interface

Recent theoretical results reported by Nyikos and Pajkossy (N-P) on fractal electrolyte/blocking electrode interfaces have been tested with numerical calculations. It is shown that (I) interfaces having electrolyte-metal boundaries in form of a generalized Koch curve do not have a constant-phase-ang

Aba~-l?tc impdancc spb\*rum ol an immd coa~cd metal specimen gcnedly contains three Ireqwncy domains: the high frequency (HF) parr represents the coating characteristic, the intennaiiate frequency (IT) part stands for the corrosion ma&on and double layer bahaviour, and chc low frequency (LF) pul is

This paper is focused on the relation between the fractal geometry of the interface and the frequency dispersion of the impedance. As proved theoretically in a previous work it is experimentally verified that on Von Koch interfaces no straight forward relation exists between fractal dimension and ex

In this work electrochemical impedance spectroscopy was carried out on pre-and post-etched Ga,,,In,,,P (1.8-1.9eV) as well as quinolinol-modified surfaces, over seven decades of frequencies. The spectra were examined in the Bode as well as complex impedance planes and deconvoluted using nonlinear-le