Electrical manipulation of magnetic anisotropy in a Fe81Ga19/PMN-PZT magnetoelectric multiferroic composite

Abstract

Magnetoelectric composites are an important class of multiferroic materials that pave the way towards a new generation of multifunctional devices directly integrable in data storage technology and spintronics. This study focuses on strain-mediated electrical manipulation of magnetization in an extrinsic multiferroic. The composite includes 5 nm or 60 nm Fe81Ga19 thin films coupled to a piezoelectric (011)-PMN-PZT. The magnetization reversal study reveals a converse magnetoelectric coefficient αCME,max ≈ 2.7 × 10-6 s.m-1 at room temperature. This reported value of αCME is among the highest so far compared to previous reports of single-phase multiferroics as well as composites. An angular dependency of αCME is also shown for the first time, arising from the intrinsic magnetic anisotropy of FeGa. The highly efficient magnetoelectric composite FeGa/PMN-PZT demonstrates drastic modifications of the in-plane magnetic anisotropy, with an almost 90 rotation of the preferential anisotropy axis in the thinner films under an electric field E = 10.8 kV.cm-1. Also, the influence of thermal strain on the bilayer's magnetic coercivity is compared to that of a reference bilayer FeGa/Glass at cryogenic temperatures. A different evolution is observed as a function of temperature, revealing a substrate thermo-mechanical influence which has not yet been reported in FeGa thin films coupled to a piezoelectric material.