Large room temperature electrocaloric effect in PbZrO3/ Ca3Mn2O7 heterostructure

Electrocaloric effects of antiferroelectric and ferroelectric films have been intensively studied for the applications in refrigeration. However, achieving high electrocaloric performance near room temperature is still very difficult in films. Herein, we report that large and regulable electrocaloric effects at room temperature are achieved in PbZrO3/Ca3Mn2O7 bilayer films based on PbZrO3 phase transition, and the sign of adiabatic temperature change, ?T, is determined by Ca3Mn2O7 thickness. The PbZrO3-Ca3Mn2O7 heterojunction formed by carrier diffusions reduces the carrier concentration of the film and establishes a built-in electric field in the junction region, and withstanding voltages of the bilayer films are enhanced greatly. The maximum positive ?T of 66.5 K was obtained in the bilayer film with a thin Ca3Mn2O7 layer, but a negative ?T of -9.9 K with a thick Ca3Mn2O7 layer, near room temperature. This work presents a simple and effective approach to designing huge electrocaloric based on antiferroelectric-containing multilayers near room temperature.

Automated summary

In this study, large and regulable electrocaloric effects at room temperature are achieved in PbZrO3/Ca3Mn2O7 bilayer films based on PbZrO3 phase transition, and the sign of adiabatic temperature change, ΔT, is determined by Ca3Mn2O7 thickness. The formed PbZrO3-Ca3Mn2O7 heterojunction reduces the carrier concentration of the film and establishes a built-in electric field, greatly enhancing the withstanding voltage of the bilayer films. A maximum positive ΔT of 66.5 K is obtained in the bilayer film with a thin Ca3Mn2O7 layer, while a negative ΔT of -9.9 K is obtained with a thick Ca3Mn2O7 layer, both near room temperature. This work presents a simple and effective approach to designing huge electrocaloric effects based on antiferroelectric-containing multilayers near room temperature.