1. A Spotter's guide to dispersion in non-catalytic surface-confined voltammetry experiments.
- Author
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Lloyd-Laney, Henry O., Robinson, Martin J., Bond, Alan M., Parkin, Alison, and Gavaghan, David J.
- Subjects
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VOLTAMMETRY , *DISPERSION (Chemistry) , *CHARGE exchange , *OXIDATION-reduction reaction , *FACTOR analysis , *DISPERSION (Atmospheric chemistry) - Abstract
• Effects of thermodynamic and kinetic dispersion in surface confined voltammetry. • Distinguishing dispersed from non-dispersed cases by looking at voltammetry data. • Thermodynamic dispersion is usually resolvable for all experiments. • Kinetic dispersion is only resolvable for certain systems under defined conditions. Dispersion, or the distribution of kinetic and thermodynamic parameter values describing a redox reaction, has long been acknowledged as a complicating factor in the analysis of both solution and surface-confined voltammetry experiments. In this tutorial paper, we show how varying levels of dispersion can affect the appearance of the experimental current, mainly illustrating the concept with reference to surface-confined reversible one electron transfer. We focus on three voltammetric techniques, ramped Fourier Transform AC Voltammetry, Purely Sinusoidal Voltammetry and Direct Current Voltammetry, showing the effect the dispersion parameters have on the appearance of the resulting current. We have also implemented an interactive web-based simulation package for comparison of the effects of the various parameters, available here. As modelling dispersion significantly increases the computational burden of simulating voltammetry experiments, making well-informed choices about when to include this effect is essential. To facilitate this, we discuss the intuition for when to include dispersion when fitting experimental voltammetry data, again with reference to the three techniques described above. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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