Journal of Electroanalytical Chemistry, Vol.683, 37-42, 2012
Modelling the steady state voltammetry of a single spherical nanoparticle on a surface
The steady-state voltammetry of a one electron reduction, A + e (sic) B, is studied numerically for a conductive spherical particle resting on a supporting surface. The process is assumed to occur exclusively on the surface of the sphere and not at all on the support. For electrode kinetics in the fully irreversible limit, we establish a simple relationship between the half-wave pore fiat and the kinetic parameters, a (the transfer coefficient) and k(0) (the rate constant of the reaction), the radius of the sphere, and the diffusion coefficient of the species in solution. Further, we develop an expression that completely describes the voltammetric waveform in the same limit. Additionally we describe a simple transformation that maps the irreversible steady-state voltammetry for an isolated spherical electrode, such as may be obtained from any commercially available electrochemical simulation package onto the voltammetry of a sphere on a surface. The sphere on a supporting plane model has recently been used to explain the current-time behaviour seen for nanoparticle impacted electrode surfaces stch that electrode process occur on the sphere surface whilst it is in contact with the plane [J.M. Kahk, N.V. Rees, J. Pillay, R. Tshikhudo, S. Vilakazi, R.G. Compton, Nano Today 7 (2012) 174-179]: accordingly, he theory presented here is of potential significant application in this area. (C) 2012 Elsevier B.V. All rights reserved.
Keywords:Sphere on a surface;Numerical simulation;Steady-stare voltammetry;Half-wave potential;Current-potential waveshape