A Critical Insight into Pretransitional Behavior and Dielectric Tunability of Relaxor Ceramics

Abstract

The model discussion focused on links between the unique properties of relaxor ceramics and the basics of critical phenomena physics and glass transition physics. It indicates the significance of uniaxiality for appearing mean-field features near paraelectricferroelectric transition. Pretransitional fluctuations, increasing up to grain size and leading to inter-grain, random, local electric fields, are indicated to be responsible for relaxor ceramics characteristics. Their impacts yield the pseudo spinodal behavior associated with weakly discontinuous local phase transitions. The emerging model redefines the meaning of the Burns temperature and polar nanoregions PNRs. It explains coherently dielectric constant changes with the diffused maximum near paraelectricferroelectric transition, the sensitivity even to moderate electric fields, tunability, and the glassy dynamics. These considerations are confronted with experimental results for the complex dielectric permittivity studies in relaxor ceramic, covering the 200K range, from the paraelectric to the deep ferroelectric phase. The distortions-sensitive and derivative-based analysis revealed the preference for the exponential scaling pattern in the paraelectric phase and the surroundings of the paraelectric-ferroelectric transition. It may suggest the Griffith phase behavior associated with the mean-field criticality disturbed by random local impacts. The discussion of experimental results is supplemented by relaxation times changes and the coupled energy losses analysis. The studies also led to the description of tunability temperature changes with scaling relations.

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