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Interfacial oxide wedging for mechanical-robust electrode in high-temperature ceramic cells

Yuan Zhang, Zhipeng Liu, Junbiao Li, Kuiwu Lin, Daqin Guan, Yufei Song, Guangming Yang, Wei Zhou, Jingjie Ge, Minhua Shao, Bin Chen, Meng Ni, Zongping Shao, Heping Xie

2025Nature Communications9 citationsDOIOpen Access PDF

Abstract

Delamination and cracking of air electrodes are two mechanical causes to the degradation of high-temperature electrochemical ceramic cells. While compositing negative thermal expansion (NTE) materials can tackle delamination by lowering the thermal expansion coefficient (TEC) of air electrode, it can exacerbate cracking due to large thermal stress between particles of NTE and positive thermal expansion perovskites (PTE). Here, we introduce interfacial oxides to “wedge” the NTE-PTE interface, thereby resisting cracking inside the bulk of the air electrode through reactive calcination at near-melting temperatures. This concept is demonstrated by compositing negative thermal expansive HfW2O8 with Ba0.5Sr0.5Co0.8Fe0.2O3–δ (perovskite), forming Co3O4, Fe3O4, BaHfO3 and Sr3WO6 as wedging phases. Enhanced bulk modulus (by 102%), hardness (by 138%), and mitigated TEC (reduced by 35%) are simultaneously achieved, which enhances the durability of the air electrode over 40 rigorous thermal cycles between 600 °C and 300 °C, and even with no decay after two years of exposure to ambient air. This method offers an effective strategy for developing mechanical-robust electrodes of high-temperature electrochemical cells. Delamination and cracking hinder the durability of air electrodes in ceramic cells. Here, the authors introduce oxide wedging at particle interfaces to enhance mechanical robustness and thermal compatibility, significantly improving electrode longevity.

Topics & Concepts

Materials scienceThermal expansionCrackingComposite materialElectrodeCeramicOxideDelamination (geology)ThermalNegative thermal expansionCalcinationDurabilityElastic modulusModulusStress (linguistics)ElectrochemistryYoung's modulusThermal barrier coatingThermal conductivityThermal Expansion and Ionic ConductivityAdvancements in Solid Oxide Fuel CellsFerroelectric and Piezoelectric Materials