The Effect of Bi2O3 and Fe2O3 Impurity Phases in BiFeO3 Perovskite Materials on Some Electrical Properties in the Low-Frequency Field

Pure bismuth ferrite (BFO) and BFO with impurity phases (Bi2O3 or Fe2O3) were synthesized by the hydrothermal method. Complex dielectric permittivity (epsilon) and electrical conductivity (sigma) were determined by complex impedance measurements at different frequencies (200 Hz-2 MHz) and temperatures (25-290) degrees C. The conductivity spectrum of samples, sigma(f), complies with Jonscher's universal law and the presence of impurity phases leads to a decrease in the static conductivity (sigma(DC)); this result is correlated with the increased thermal activation energy of the conduction in impure samples compared to the pure BFO sample. The conduction mechanism in BFO and the effect of impurity phases on sigma and epsilon were analyzed considering the variable range hopping model (VRH). Based on the VRH model, the hopping length (R-h), hopping energy (W-h) and the density of states at the Fermi level (N(E-F)) were determined for the first time, for these samples. In addition, from epsilon(T) dependence, a transition in the electronic structure of samples from a semiconductor-like to a conductor-like behavior was highlighted around 465-490 K for all samples. The results obtained are useful to explain the conduction mechanisms from samples of BFO type, offering the possibility to develop a great variety of electrical devices with novel functions.

Automated summary

In this study, pure bismuth ferrite and bismuth ferrite with impurity phases were synthesized and their electrical properties were analyzed. The presence of impurity phases was found to decrease the static conductivity and increase the thermal activation energy of conduction in the samples. By studying the transition in electronic structure at specific temperatures, the conduction mechanisms in these materials were better understood.