Abstract
The hypothesis that laser activation of glassy carbon (GC) electrodes is thermally driven was investigated by comparing simulated surface temperatures for several lasers and experimental conditions. Assuming no phase changes, the surface temperature vs. time profile for a laser pulse striking a GC electrode was predicted by finite difference simulation. It was predicted that peak surface temperature depends on power density, wavelength, pulse duration and the optical properties of the carbon. Experimentally, laser activation is weakly wavelength dependent for ascorbic acid and Fe 2+ 3+ . The surface temperatures required for activation were consistent for different lasers, supporting the conclusion that laser activation is thermally driven. Furthermore, predicted surface temperatures during activation were below the melting point of carbon but well above the boiling point of water. The results should be useful for predicting the effectiveness of different laser conditions on electron transfer activation.
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