4.6 Article

Electrochemical microelectrode degradation monitoring: in situ investigation of platinum corrosion at neutral pH

Journal

JOURNAL OF NEURAL ENGINEERING
Volume 19, Issue 1, Pages -

Publisher

IOP Publishing Ltd
DOI: 10.1088/1741-2552/ac47da

Keywords

platinum; corrosion; implant; neural interface; electrochemical sensor; thin-film

Funding

  1. Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) [FOR 2383, DI696/13-2, UR70/11-2]
  2. BrainLinks-BrainTools Center, project 'INTEREST'

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This study investigates the degradation of platinum microelectrodes in neutral pH and chloride-containing electrolytes using continuous electrochemical methods. The findings show that electrode degradation is mainly driven by the formation and removal of platinum surface oxide. These results provide valuable information on the stability of platinum microelectrodes in biomedical applications.
Objective. The stability of platinum and other noble metal electrodes is critical for neural implants, electrochemical sensors, and energy sources. Beyond the acidic or alkaline environment found in most electrochemical studies, the investigation of electrode corrosion in neutral pH and chloride containing electrolytes is essential, particularly regarding the long-term stability of neural interfaces, such as brain stimulation electrodes or cochlear implants. In addition, the increased use of microfabricated devices demands the investigation of thin-film electrode stability in combination with electrode performance. Approach. We developed a procedure of electrochemical methods for continuous tracking of electrode degradation in situ over the complete life cycle of platinum thin-film microelectrodes in a unique combination with simultaneous chemical sensing. We used chronoamperometry and cyclic voltammetry to measure electrode surface and analyte redox processes, together with accelerated electrochemical degradation. Main results. We compared degradation between thin-film microelectrodes and bulk electrodes, neutral to acidic pH, different pulsing schemes, and the presence of the redox active species oxygen and hydrogen peroxide. Results were confirmed by electrochemical impedance spectroscopy, as well as mechanical profilometry and microscopy to determine material changes on a nanometer scale. We found that electrode degradation is mainly driven by repeated formation and removal of the platinum surface oxide, also within the electrochemical stability window of water. There was no considerable difference between thin-film micro- and macroscopic bulk electrodes or in the presence of reactive species, whereas acidic pH or extending the potential window led to increased degradation. Significance. Our results provide valuable fundamental information on platinum microelectrode degradation under conditions found in biomedical applications. For the first time, we employed a unified method to report quantitative data on electrode degradation up to a defined endpoint. Our method is a widely applicable framework for comparative long-term studies of electrode micro-/nanomaterial, sensor and neural interface stability.

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