The Electrodegradation Process in PZT Ceramics under Exposure to Cosmic Environmental Conditions

Long-time electric field action on perovskite piezoelectric ceramic leads to chemical degradation. A new way to accelerate the degradation is the exposure of the ceramic to DC electric fields under a vacuum. A high-quality commercial piezoelectric material based on PbZr1-xTixO3 is used to study such impacts. To avoid the influence of ferroelectric properties and possible removal of oxygen and lead oxides during the degradation process, the experiments are in the temperature interval of 500 degrees C > T > T-C. Changes in resistance during the electrodegradation process is an electrically-induced deoxidation, transforming the ceramic into a metallic-like material. This occurs with an extremely low concentration of effused oxygen of 10(16) oxygen atoms per 1 cm(3). Due to this concentration not obeying the Mott criterion for an isolator-metal transition, it is stated that the removal of oxygen mostly occurs along the grain boundaries. It agrees with the first-principle calculations regarding dislocations with oxygen vacancies. The decrease in resistivity during electrodegradation follows a power law and is associated with a decrease in the dislocation dimension. The observed reoxidation process is a lifeline for the reconstructing (self-healing) properties of electro-degraded ceramics in harsh cosmic conditions. Based on all of these investigations, a macroscopic and nanoscopic model of the electrodegradation is presented.

Automated summary

Long-time electric field action causes chemical degradation in perovskite piezoelectric ceramics. A new method to accelerate this degradation is by exposing the ceramics to DC electric fields under vacuum. The study focuses on a high-quality commercial piezoelectric material based on PbZr1-xTixO3. The resistance changes during electrodegradation, resulting in electrically-induced deoxidation and transformation of the ceramic into a metallic-like material.