posted on 2018-12-24, 00:00authored byAnil Koklu, Amin Mansoorifar, Jason Giuliani, Carlos Monton, Ali Beskok
Electrode polarization
effects were investigated using impedance
spectroscopy measurements for planar and nanorod-structured gold disk
electrodes at 100 Hz to 1 MHz frequency range and in 0.25 S/m to 1.5
S/m conductivity KCl solutions. Diameters of planar electrodes were
varied from 50 μm to 2 mm to examine the effect of electrode
size on impedance spectra. Normalizing the impedance magnitude with
the spreading resistance and frequency with the characteristic time
scale, all experimental data collapsed onto a universal curve, proving
self-similarity. Experimental impedance results were compared well
with that obtained from the numerical solution of Poisson–Nernst–Planck
equations in axisymmetric domain. The influence of surface morphology
was also investigated by generating cylindrical nanorods on a planar
electrode. The 500 μm diameter electrode surface was covered
with cylindrical nanorods with known height, diameter, and separation
distance, which were characterized using scanning electron microscopy.
The characteristic time scale for the nanorod-structured electrode
increased by the surface enlargement factor obtained by cyclic voltammetry
measurements. Self-similar interfacial impedance of electrodes was
modeled using a constant phase element model. Current findings describe
the coupled effects of electrode diameter, electrolyte conductivity,
and electrode surface morphology on the impedance spectra of electrode/electrolyte
system when the electric double layer between the nanorods does not
overlap.