Stable antiferroelectric phase in calcium-doped lead scandium tantalate

Abstract: Antiferroelectrics are valuable dielectric materials, offering promise for both high energy storage and solid-state caloric cooling applications. However, few antiferroelectrics are known or available. Therefore, it is crucial to discover or design materials showing antiferroelectric behaviour. In this study, we fabricated highly ordered lead scandium tantalate ceramics doped with calcium. From calorimetry and polarization-electric field loops, we demonstrate the effect of calcium on the thermal properties and phase transition sequences of lead scandium tantalate. We identify an antiferroelectric phase appearing at temperatures intermediate between the ferroelectric and paraelectric phases, which becomes increasingly stable as the calcium concentration increases. These findings are supported by density functional theory calculations and Raman spectroscopy. Finally, we propose a phase diagram for calcium-doped lead scandium tantalate. Our results highlight the potential of stabilizing antiferroelectricity in ferroelectric perovskite materials through A-site doping.