Electrochemical oscillations of nickel electrodissolution in an epoxy-based microchip flow cell

We investigate the nonlinear dynamics of transpassive electrodissolution of nickel in sulfuric acid in an epoxy-based microchip flow cell. We observed bistability, smooth, relaxation, and period-2 waveform current oscillations with external resistance attached to the electrode in the microfabricated electrochemical cell with 0.05 mm diameter Ni wire under potentiostatic control. Experiments with 1 mm × 0.1 mm Ni electrode show spontaneous oscillations without attached external resistance; similar surface area electrode in macrocell does not exhibit spontaneous oscillations. Combined experimental and numerical studies show that spontaneous oscillation with the on-chip fabricated electrochemical cell occurs because of the unusually large ohmic potential drop due to the constrained current in the narrow flow channel. This large IR potential drop is expected to have an important role in destabilizing negative differential resistance electrochemical (e.g., metal dissolution and electrocatalytic) systems in on-chip integrated microfluidic flow cells. The proposed experimental setup can be extended to multi-electrode configurations; the epoxy-based substrate procedure thus holds promise in electroanalytical applications that require collector–generator multi-electrodes wires with various electrode sizes, compositions, and spacings as well as controlled flow conditions.

Transpassive dissolution of 0.05 mm diameter Ni electrode in microintegrated, epoxy-based flow cell (left) exhibits simple periodic, period-2, and relaxation type current oscillations (right) under potentiostatic conditions.Figure optionsDownload as PowerPoint slideHighlights
► Nonlinear dynamics of transpassive Ni electrodissolution is studied.
► Ni wires are embedded in epoxy.
► Microfluidic poly(dimethylsiloxane) flow channel is positioned over the wires.
► Simple smooth, relaxational, and complex period-2 current oscillations are recorded.
► Oscillations are interpreted based on potential drop in the flow channel.