Abstract
The temperature dependence of the dielectric response of ordinary ferroelectric materials exhibits a frequency-independent anomalous peak as a manifestation of the ferroelectric to paraelectric phase transition. A second anomaly in the permittivity has been reported in different ferroelectric perovskite-type systems at low temperatures, often at cryogenic temperatures. This anomaly manifests as a frequency-dependent local maximum, which exhibits similar characteristics to that observed in relaxor ferroelectrics around their phase transition. The origin of this unexpected behavior is still controversial. In order to clarify this phenomenon, a model-free route solution is developed in this work. Our findings reveal the same critical linear pattern/glass-like freezing behavior previously observed for glass-forming systems. Contrary to current thought, our results suggest that a critical-like dynamic parameterization could provide a more appropriate solution than the conventional Vogel–Fulcher–Tammann equation. The implemented methodology may open a new pathway for analyzing relaxation phenomena in other functional materials like relaxor ferroics.
Highlights
The study of the temperature and frequency dependence of the dielectric response has proven to be a helpful tool in condensed matter physics
An analysis is conducted into the dynamics of some PZT-based materials, which are one of the most broadly tested ferroelectrics studied to date
The results indicate that a direct analysis of the fitting quality of t (T ) is discouraging and inconclusive, since no statistical criterion exists for considering a model equation to be predominant for the dielectric relaxation
Summary
Commons Attribution 3.0 frequency-independent anomalous peak as a manifestation of the ferroelectric to paraelectric phase licence. Any further distribution of this work must maintain perovskite-type systems at low temperatures, often at cryogenic temperatures. This anomaly manifests attribution to the author(s) and the title of as a frequency-dependent local maximum, which exhibits similar characteristics to that observed in the work, journal citation relaxor ferroelectrics around their phase transition. The origin of this unexpected behavior is still and DOI. The implemented methodology may open a new pathway for analyzing relaxation phenomena in other functional materials like relaxor ferroics
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