Design of high polarization low switching barrier hybrid improper ferroelectric perovskite oxide superlattices

Abstract

Hybrid improper ferroelectricity is a useful tool to design ABO₃/A′BO₃ polar superlattices from non polar building blocks. In this study, we have designed high polarization-low switching barrier hybrid improper ferroelectric superlattices with efficient polarization, and polarization-magnetization switching properties above room temperature, using density functional theory and ab initio molecular dynamics simulations. Superlattices with a chemical formula of (AAlO₃)_m/(A′AlO₃)_n, where m/n = 1/1, 1/3, 3/1, 1/5 and 5/1, A, A′ = Lanthanide and Y cations are considered to outline the design principles behind polarization switching and (LaFeO₃)₃/(CeFeO₃)₁ is investigated for polarization-magnetization switching. We find that the unconventional switching paths via out-of-phase rotation Q_R− (a⁰a⁰c⁻) and tilt precession Q_TP always yield lower switching barrier compared to those via in-phase rotation Q_R+ (a⁰a⁰c⁺) and tilt Q_T (a⁻a⁻c⁰) of BO₆ octahedra. Results from ab initio molecular dynamics simulations estimate the temperature at which the lowest energy barrier can be overcome. It is possible to tune the polarization switching barrier by tuning the tolerance factor, A,A′ cation radius mismatch and super lattice periodicity. For switching via Q_R−, the switching barrier varies exponentially with rotation angle, indicating how high switching barrier is expected for systems, away from cubic symmetry. We provide a recipe to overcome such a bottleneck by tuning superlattice periodicity. Finally, we have proposed the multiferroic device application concept through a proposed polarization-temperature hysteresis loop and magnetization switching.