Atomic force microscopy-scanning electrochemical microscopy: influence of tip geometry and insulation defects on diffusion controlled currents at conical electrodes

Kelly Leonhardt; Amra Avdic; Alois Lugstein; Ilya Pobelov; Thomas Wandlowski; Ming Wu; Bernhard Gollas; Guy Denuault

doi:10.1021/ac103083y

Atomic force microscopy-scanning electrochemical microscopy: influence of tip geometry and insulation defects on diffusion controlled currents at conical electrodes

Anal Chem. 2011 Apr 15;83(8):2971-7. doi: 10.1021/ac103083y. Epub 2011 Mar 28.

Authors

Kelly Leonhardt¹, Amra Avdic, Alois Lugstein, Ilya Pobelov, Thomas Wandlowski, Ming Wu, Bernhard Gollas, Guy Denuault

Affiliation

¹ School of Chemistry, Highfield Campus, University of Southampton, Southampton, SO17 1BJ, United Kingdom.

PMID: 21443173
DOI: 10.1021/ac103083y

Abstract

Numerical simulations were performed to predict the amperometric response of conical electrodes used as atomic force microscopy-scanning electrochemical microscopy (AFM-SECM) probes. A simple general expression was derived which predicts their steady state limiting current as a function of their insulation sheath thickness and cone aspect ratio. Simulated currents were successfully compared with experimental currents. Geometrical parameters such as insulation angle and tip bluntness were then studied to determine their effect on the limiting current. Typical tip defects were also modeled using 3D simulations, and their influence on the current was quantified. Although obtained for SECM-AFM probes, these results are directly applicable to conical micro- and nanoelectrodes.