Optimizing the stability and electrical transport properties of CeNbO4+δ-based oxide ceramics by regulating oxygen ion content

CeNbO4+delta ceramics have attracted extensive research interest because of their unique mixed ion-electron transport characteristics and interesting structure-functional characteristics caused by the difference in oxygen ion content. Although the change of oxygen ion content brings rich redox properties, it also causes serious crystal transformation and abnormal electrical transport properties. In order to obtain stable structure and excellent electrical transport properties, the directional regulation of the oxygen ion content has been realized through introducing Al2O3 and high temperature aging. After 600 h of aging at 1073 K, the prepared composite ceramics not only obtain a stable structure without crystal transformation, but also show good negative temperature coefficient (NTC) thermistor characteristics in the temperature range of 473 K-1273 K, in which the linear fitting maximum Pearson's r of the relationship between ln rho and 1000/T can reach 99.97%. The proposed method provides a new thought for the design and application of high-temperature electronic ceramics.

Automated summary

CeNbO4+Δ ceramics have unique mixed ion-electron transport characteristics and interesting structure-functional characteristics due to the difference in oxygen ion content, attracting extensive research interest. The directional regulation of oxygen ion content has been achieved by introducing Al2O3 and high temperature aging, resulting in stable structure and excellent electrical transport properties.