Studies of structural, dielectric and impedance spectroscopy of Ca/Zr modified BiFeO3 ceramics

In this communication, the structural and electrical (dielectric, polarization, impedence, and conductivity) properties of the polycrystalline samples of Ca/Zr modified BiFeO3 samples with chemical formula (Bi-1-Ca-x(x)) (Fe-1-Zr-x(x))O-3; x = 0.05, 0.1, 0.15, 0.20 were prepared using a solid-state reaction method at 800 degrees C have been reported. The analysis of room temperature X-ray diffraction data of above-synthesized electro-ceramics confirms the formation of single phase perovskite in rhombohedral phase. The scanning electron microscope photographs provide the micro-structural study of the samples. The existence of ferroelectricity in the materials was studied by the variation of electric polarization with the applied electric field. Many important results have been obtained from the dielectric and impedance studies of the samples at a varying frequency (1 kH(Z)-1000 kH(z)) and temperature (25 degrees C-300 degrees C). The contribution of both grains and grain boundaries towards the total resistance and capacitance of the four compounds is found from the Nyquist plots. From the conductivity study, the dielectric properties and conductivity of the materials were obtained. The J-E characteristics of the samples provide the Ohmic behavior with slope closer to 1.

Automated summary

This study reported the structural and electrical properties of Ca/Zr modified polycrystalline BiFeO3 samples prepared by solid-state reaction method, revealing the formation of single phase perovskite in rhombohedral phase and the ferroelectricity in the materials. Analysis of X-ray diffraction data and scanning electron microscope images provided insights into the micro-structure, while dielectric, impedance and conductivity studies offered information on the dielectric properties and conductivity of the materials. Additionally, the contribution of grains and grain boundaries towards the total resistance and capacitance was determined from Nyquist plots. The J-E characteristics demonstrated Ohmic behavior with a slope close to 1.