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Effect of volume fractions and aging on Ni-GDC SOFC anode degradation and performance: multiphase-field simulations

Jeela, Ravi Kumar 1; Elmoghazy, Ahmed 1; Schöller, Lukas 1; Wieler, Matthias; Prahs, Andreas ORCID iD icon 1,2; Schneider, Daniel ORCID iD icon 1,2; Nestler, Britta 1,2
1 Institut für Angewandte Materialien – Mikrostruktur-Modellierung und Simulation (IAM-MMS), Karlsruher Institut für Technologie (KIT)
2 Institut für Nanotechnologie (INT), Karlsruher Institut für Technologie (KIT)

Abstract:

Enhancing the performance and durability of solid oxide fuel cells (SOFCs) requires concurrent improvements in electrochemical activity and mechanical integrity, both strongly dependent on the initial anode microstructure and its degradation over long-term operation. This study presents a comprehensive degradation investigation for nickel-gadolinium doped ceria (Ni-GDC) SOFC anode microstructures, combining the generation of realistic synthetic microstructures and large-scale aging simulations. Synthetic microstructures are generated and quantitatively validated against experimental reconstructions of Ni-GDC employing an enhanced structure generator workflow that incorporates sintering-like morphological coalescence, resulting in digital twins for optimization studies. Representative synthetic microstructures are generated with systematically varying phase volume fractions and subjected to long-term (2000 h) aging using a validated multiphase-field model. Electrochemical performance descriptors, including triple-phase boundary (TPB), double-phase boundary (DPB) densities, phase tortuosities, and mechanical properties, such as elastic moduli and stress distributions resulting from thermal expansion coefficient mismatch between Ni and GDC, are collectively analyzed. ... mehr


Verlagsausgabe §
DOI: 10.5445/IR/1000195019
Veröffentlicht am 07.07.2026
Originalveröffentlichung
DOI: 10.1038/s41529-026-00811-x
Cover der Publikation
Zugehörige Institution(en) am KIT Institut für Nanotechnologie (INT)
Institut für Angewandte Materialien – Mikrostruktur-Modellierung und Simulation (IAM-MMS)
Publikationstyp Zeitschriftenaufsatz
Publikationsjahr 2026
Sprache Englisch
Identifikator ISSN: 2397-2106
KITopen-ID: 1000195019
Erschienen in npj Materials Degradation
Verlag Nature Research
Band 10
Heft 1
Seiten 82
Vorab online veröffentlicht am 29.05.2026
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