Numerical simulation of alternating current linear sweep voltammetry at microdisc electrodes

We extend our earlier work on the numerical simulation of ac linear sweep v oltammetry at macroelectrodes to the case of microdisc electrodes. This req uires the solution of the underlying diffusional transport equations in two dimensions, rather than one, using a cylindrical coordinate system. We use the two-dimensional FIRM algorithm combined with a specially designed expo nentially expanding mesh. We examine the ac response as a function of the f requency and amplitude of the ac signal, and as a function of the non-dimen sional parameter p = (nFa(2)v/RTD)(1/2), where a is electrode radius, v the sweep rate, and D the diffusion coefficient. Results are analysed using Fa st Fourier Transform (FFT) methods. We are able to derive a range of condit ions under which radial diffusion has only a minor effect on the ac respons e of the system. The analytical results available for macroelectrodes there fore carry through to the microelectrode case for many practical ranges of system parameters (electrode size, dc sweep rate and diffusion coefficient) . Experimental results are given which show good agreement with the numeric al simulations.