Temperature dependent magnetoelectric response of lead-free Na0.4K0.1Bi0.5TiO3-NiFe2O4 laminated composites

Abstract

This study investigates the temperature-dependent quasi-static magnetoelectric (ME) response of electrically poled lead-free Na0.4K0.1Bi0.5TiO3-NiFe2O4 (NKBT-NFO) laminated composites. The aim is to understand the temperature stability of ME-based sensors and devices. The relaxor ferroelectric nature of NKBT is confirmed through impedance and polarization-electric (PE) hysteresis loop studies, with a depolarization temperature (Td) of approximately 110. Heating causes a decrease and disappearance of planar electromechanical coupling, charge coefficient, and remnant polarization above Td. The temperature rise also leads to a reduction in magnetostriction and magnetostriction coefficient of NFO by approximately 33% and 25%, respectively, up to approximately 125. At room temperature, the bilayer and trilayer configurations exhibit maximum ME responses of approximately 33 mV/cm.Oe and 80 mV/cm.Oe, respectively, under low magnetic field conditions (300-450 Oe). The ME response of NKBT/NFO is highly sensitive to temperature, decreasing with heating in accordance with the individual temperature-dependent properties of NKBT and NFO. This study demonstrates a temperature window for the effective utilization of NKBT-NFO-based laminated composite ME devices.