Influence of calcination and sintering temperatures on dielectric and magnetic properties of Pb(Fe0.5Nb0.5)O3 ceramics synthesized by the solid state method

Lead iron niobate, Pb(Fe0.5Nb0.5)O3 (PFN), belongs to the family of multiferroic materials combining ferroelectric and antiferromagnetic ordering. Its properties to a large extent depend on the synthesis conditions. For applications it is important to obtain materials with large polarization and low electric leakage. In this paper we investigate the effect of processing parameters on the structural, electrical and magnetic behaviour of PFN ceramics prepared by the solid state method. The optimal calcination and sintering temperatures are found, which enable us to obtain ceramics with a large polarization Pmax = 28 mu C/cm2 and dielectric permittivity epsilon Max approximate to 55 000. We also find that increasing the calcination and sintering temperatures decreases diffuseness of the ferroelectric phase transition and shifts the Ne ' el temperature to lower values, which might be due to a change of the distribution of Fe3+ and Nb5+ across the B-sites of the perovskite towards a more ordered structure.

Automated summary

Lead iron niobate (PFN) is a multiferroic material with properties highly dependent on synthesis conditions. By optimizing calcination and sintering temperatures, ceramics with large polarization and dielectric permittivity can be obtained. Increasing temperatures also affects the ferroelectric phase transition and Ne ' el temperature due to a change in the distribution of Fe3+ and Nb5+ ions.