Enhanced electrocaloric, pyroelectric and energy storage performance of BaCexTi1−xO3 ceramics

Abstract

BaCexTi1−xO3 (BCT) ceramics with compositions x=0, 0.1, 0.12 and 0.15 were synthesized using conventional solid state reaction route. Systematic exploration of enhancing electrocaloric effect (ECE) in BaTiO3 by rare earth dopant Ce is presented. BaCe0.12Ti0.88O3 exhibited an electrocaloric strength of ∼0.35Km/MV at 351K, which caters the need for a series of high-level ECE material. Further, the temperature dependence of pyroelectric coefficient is established for all compositions. The pyroelectric figure of merits (FOMs) for current responsivity (Fi), voltage responsivity (Fv), detectivity (Fd) and energy harvesting (Fe and Fe*) are calculated and the results reveal that x=0.1 could be a technologically superior candidate for pyroelectric devices. Further, BaCe0.15Ti0.85O3 exhibited highest electrical energy storage performance of 115kJ/m3 compared with 71kJ/m3 in BaTiO3. Our findings in this work may provide a better understanding for developing high ECE materials combined with pyroelectric and energy storage performance of Ce substituted BaTiO3 ceramics.