Microscopic Origin of Polarization-Controlled Magnetization Switching in FePt/BaTiO3

Abstract

Electric-field driven magnetization switching in FePt/BaTiO3 (001) is demonstrated through first-principles calculations. The magnetic easy axis of FePt layer undergoes a transition from in-plane to perpendicular direction upon ferroelectric polarization reversal, a process sensitively controlled by epitaxial strain with threshold strain strain(η) η≈\%. At this phenomena, a large interfacial magnetoelectric coupling (αI = 3.6 × 10-10 G·cm2/V) is responsible, stemming from the orbital reconstruction. In particular, the redistribution of Pt-d orbital occupancy alters spin-orbit coupling, thereby tuning the competition between magnetic anisotropy (Ki) and magnetoelastic energy (b1). Our work clarifies the fundamental physics of strain-engineered magnetoelectricity and suggests a concrete pathway for designing ultra-low-power voltage-controlled magnetic memory.