Anomalous Effect of Flow Rate on the Electrochemical
Behavior at a Liquid|Liquid Interface under Microfluidic Conditions
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Abstract
We
have investigated the oxidation of ferrocene at a flowing organic
solvent|aqueous electrolyte|solid electrode junction in a microfluidic
setup using cyclic voltammetry and fluorescent laser scanning confocal
microscopy. At low flow rates the oxidation current decreases with
increasing flow, contrary to the Levich equation, but at higher flow
rates the current increases linearly with the cube root of the flow
rate. This behavior is explained using a simple model postulating
a smallest effective width of the three-phase junction, which after
fitting to the data comes to be ca. 20 μm. The fluorescence
microscopy reveals mixing of the two phases close to the PDMS cover,
but the liquid|liquid junction is stable close to the glass support.
This study shows the importance of the solid|liquid|liquid junctions
for the behavior of multiphase systems under microfluidic conditions