Simulation of the Electrochemical Impedance in a Three-Dimensional, Complex Microstructure of Solid Oxide Fuel Cell Cathode and Its Application in the Microstructure Characterization.

Vishwas Goel,Dalton Cox,Scott A Barnett,Katsuyo Thornton

doi:10.3389/fchem.2021.627699

Vishwas Goel, Dalton Cox + Show 2 more

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https://doi.org/10.3389/fchem.2021.627699

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Abstract

Electrochemical impedance spectroscopy (EIS) is a powerful technique for material characterization and diagnosis of the solid oxide fuel cells (SOFC) as it enables separation of different phenomena such as bulk diffusion and surface reaction that occur simultaneously in the SOFC. In this work, we simulate the electrochemical impedance in an experimentally determined, three-dimensional (3D) microstructure of a mixed ion-electron conducting (MIEC) SOFC cathode. We determine the impedance response by solving the mass conservation equation in the cathode under the conditions of an AC load across the cathode’s thickness and surface reaction at the pore/solid interface. Our simulation results reveal a need for modifying the Adler-Lane-Steele model, which is widely used for fitting the impedance behavior of a MIEC cathode, to account for the difference in the oscillation amplitudes of the oxygen vacancy concentration at the pore/solid interface and within the solid bulk. Moreover, our results demonstrate that the effective tortuosity is dependent on the frequency of the applied AC load as well as the material properties, and thus the prevalent practice of treating tortuosity as a constant for a given cathode should be revised. Finally, we propose a method of determining the aforementioned dependence of tortuosity on material properties and frequency by using the EIS data.

Highlights

With rising CO2 levels in the atmosphere, low emission energy technologies for energy conversion and storage are needed to mitigate further increases in the global temperature
The operating temperature has been reduced by the use of electrocatalytically active mixed ion-electron conducting (MIEC) cathodes such as (La,Sr) (Co,Fe)O3–δ (LSCF) (Hwang et al, 2005; Liu et al, 2013; Niania et al, 2020) and Sr(Ti,Fe)O3–δ (STF) (Yoo and Bouwmeester, 2012; Perry et al, 2015; Nenning et al, 2017), wherein the oxygen evolution reactions (OERs) and oxygen reduction reactions (ORRs) occur over the entire surface
We show that the Electrochemical impedance spectroscopy (EIS) data of a solid oxide fuel cells (SOFC) MIEC cathode can be used to determine the tortuosity of the solid phase within the cathode

Summary

Introduction

With rising CO2 levels in the atmosphere, low emission energy technologies for energy conversion and storage are needed to mitigate further increases in the global temperature. Such technologies in active research and development include, Li-ion batteries (Nitta et al, 2015), supercapacitors (Zhang L. et al, 2018), and several types of fuel cells like polymer electrolyte membrane fuel cells (PEMFC) (Wang et al, 2020), solid acid fuel cells (SAFC) (Lim et al, 2020), biofuel cells (BFC) (Shakeel et al, 2019), and solid oxide fuel cells (SOFC) (Mahato et al, 2015). It is important to accurately determine the tortuosity of a cathode microstructure and optimize it to enable high performance at low operating temperatures

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