An approach to the analysis of the impedance spectra of solid oxide fuel cell using the DRT technique

Determination of the polarization resistance of the anode and cathode in a solid oxide fuel cell (SOFC) with a thin-film electrolyte is a complicated task due to the difficulty of the manufacturing the reference electrode. In this case, only the total polarization resistance of the electrodes is available for analysis. When the relaxation times of the electrode processes are close, the separation of the electrode reactions, in most cases, is impossible by the conventional nonlinear least-squares method due to a several reaction processes in anode and cathode. In this paper, using a fuel cell with a supporting cathode as an example it is shown that the distribution of relaxation times (DRT) technique for the analysis of the impedance spectra of the fuel cell can be used to determine the polarization resistance of the cathode and anode. This becomes possible at comparing and analyzing the DRT functions obtained by varying the composition of gas mixtures at the cathode and anode of the fuel cell, using an electrocatalyst to accelerate the cathode reaction as well as comparing the DRT functions of the fuel cell with the supporting cathode to the DRT functions of cells with supporting electrolyte and symmetric electrodes. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This paper introduces the use of Distribution of Relaxation Times (DRT) technique for analyzing the impedance spectra of fuel cells to determine the polarization resistance of the cathode and anode. By comparing and analyzing the DRT functions obtained under different experimental conditions, an accurate measurement of the polarization resistance can be achieved.