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Closed-Pore Formation in Oxygen Electrodes for Solid Oxide Electrolysis Cells Investigated by Impedance Spectroscopy

Martin Krammer, Alexander Schmid, Andreas Nenning, Andreas E. Bumberger, Matthäus Siebenhofer, Christopher Herzig, Andreas Limbeck, Christoph Rameshan, Markus Kubicek, Jürgen Fleig

2023ACS Applied Materials & Interfaces10 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Electrochemical impedance spectroscopy was used to investigate the chemical capacitance of La 0.6 Sr 0.4 CoO 3−δ (LSC) thin-film electrodes under anodic polarization (i.e., in the electrolysis mode). For this purpose, electrodes with different microstructures were prepared via pulsed-laser deposition. Analysis of dense electrodes and electrodes with open porosity revealed decreasing chemical capacitances with increasing anodic overpotentials, as expected from defect chemical considerations. However, extremely high chemical capacitance peaks with values in the range of 10 4 F/cm 3 at overpotentials of >140 mV were obtained after annealing for several hours in synthetic air and/or after applying high anodic bias voltages of >750 mV. From the results of several surface analysis techniques and transmission electron microscopy, it is concluded that closed pores develop upon both of these treatments: (i) During annealing, initially open pores get closed by SrSO 4, which forms due to strontium segregation in measurement gases with minute traces of sulfur. (ii) The bias treatment causes mechanical failure and morphological changes including closed pores in the bulk of dense films. Under anodic polarization, high-pressure oxygen accumulates in those closed pores, and this causes the capacitance peak. Model calculations based on a real-gas equation allow us to properly predict the experimentally obtained capacitance increase. We demonstrate that analysis of the chemical capacitance of oxygen electrodes in solid oxide electrolysis cells can thus be used as a nondestructive observation tool to detect and quantify closed porosity with a lower detection limit between 10 –4 and 10 –3 .

Topics & Concepts

Materials scienceDielectric spectroscopyElectrolysisElectrodeCapacitanceAnodeOxideAnnealing (glass)Polarization (electrochemistry)Analytical Chemistry (journal)PorosityElectrochemistryChemical engineeringComposite materialMetallurgyChemistryChromatographyElectrolytePhysical chemistryEngineeringAdvancements in Solid Oxide Fuel CellsElectronic and Structural Properties of OxidesGas Sensing Nanomaterials and Sensors