Synthetical designing of solid oxide fuel cell electrodes: Effect of particle size and volume fraction

Solid oxide fuel cell (SOFC) electrode microstructures composed of catalyst, electrolyte and pore phases with various microstructural features are synthetically generated and the effects of the mean particle size and volume fraction of each phase on three/triple phase boundaries (TPBs) are computed....

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Bibliographic Details
Published in:International journal of hydrogen energy 2022-08, Vol.47 (73), p.31446-31458
Main Authors: Timurkutluk, Bora, Ciflik, Yelda, Altan, Tolga, Genc, Omer
Format: Article
Language:English
Subjects:
Electrode
Microstructure
Solid oxide fuel cell
Synthetic microstructure generation
Three/triple phase boundaries
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Summary:Solid oxide fuel cell (SOFC) electrode microstructures composed of catalyst, electrolyte and pore phases with various microstructural features are synthetically generated and the effects of the mean particle size and volume fraction of each phase on three/triple phase boundaries (TPBs) are computed. For mono-sized particles with an equal volume fraction, the active and total TPB density are found to decrease with increasing the mean particle size due to decreased surface area. However, both are found to be inversely related to the square of the mean particle size. Active TPB densities of 37.62 μm μm−3, 9.27 μm μm−3 and 4.11 μm μm−3 are obtained from the electrode microstructures with mono-sized particles of 0.25 μm, 0.50 μm and 0.75 μm mean particle size, respectively. Moreover, ∼94% of the total TPB density is determined to be active regardless of the mean particle size. TPBs for the polydisperse particles with the same volume fraction also show a decreasing trend with the mean particle size in general. However, no significant change is observed in inactive TPB formations even for the largest particle size investigated, revealing almost fully percolated phases can be achieved when the volume fraction of each phase is equal (∼33.3%). On the other, when the volume fractions are also varied, the active TPB is shown to be strongly depended on the volume fraction of the phase having the highest mean particle size. In this regard, among the related cases studied, the lowest active TPB density is computed as 0.25 μm μm−3, whereas the highest one is measured as 26.64 μm μm−3. •Synthetic SOFC electrode microstructures with various properties are generated.•Effects of mean particle size and electrode composition on TPBs are investigated.•Active, inactive and total TPBs are computed for each microstructure generated.•The volume fraction for any phase should be decided according to its particle size.•A phase with larger particle size requires higher volume fraction to improve TPBs.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2022.07.071